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Settings.cpp
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Settings.cpp
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#include "Settings.h"
/* ----- Platform related defines - START ----- */
#if defined(CONTROLLINO_MEGA)
#include <Controllino.h>
#elif defined(CONTROLLINO_MAXI)
#include <Controllino.h>
#elif defined(CONTROLLINO_MAXI_AUTOMATION)
#include <Controllino.h>
#elif defined(ARDUINO_AVR_MEGA2560)
/* nothing needed here */
#else
#error "Unsupported board"
#endif
/* ----- Platform related defines - END ----- */
#if defined(CONTROLLINO_MEGA)
/* The input pin array */
static byte Settings::digitIN[IN_PINS] = { CONTROLLINO_A0,
CONTROLLINO_A1,
CONTROLLINO_A2,
CONTROLLINO_A3,
CONTROLLINO_A4,
CONTROLLINO_A5,
CONTROLLINO_A6,
CONTROLLINO_A7,
CONTROLLINO_A8,
CONTROLLINO_A9,
CONTROLLINO_A10,
CONTROLLINO_A11,
CONTROLLINO_A12,
CONTROLLINO_A13,
CONTROLLINO_A14,
CONTROLLINO_A15,
CONTROLLINO_I16,
CONTROLLINO_I17,
CONTROLLINO_I18,
CONTROLLINO_IN0,
CONTROLLINO_IN1,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN };
/* The output pin array */
static byte Settings::digitOUT[OUT_PINS] = { CONTROLLINO_D0,
CONTROLLINO_D1,
CONTROLLINO_D2,
CONTROLLINO_D3,
CONTROLLINO_D4,
CONTROLLINO_D5,
CONTROLLINO_D6,
CONTROLLINO_D7,
CONTROLLINO_D8,
CONTROLLINO_D9,
CONTROLLINO_D10,
CONTROLLINO_D11,
CONTROLLINO_D12,
CONTROLLINO_D13,
CONTROLLINO_D14,
CONTROLLINO_D15,
CONTROLLINO_D16,
CONTROLLINO_D17,
CONTROLLINO_D18,
CONTROLLINO_D19,
CONTROLLINO_D20,
CONTROLLINO_R0,
CONTROLLINO_R1,
CONTROLLINO_R2,
CONTROLLINO_R3,
CONTROLLINO_R4,
CONTROLLINO_R5,
CONTROLLINO_R6,
CONTROLLINO_R7,
CONTROLLINO_R8,
CONTROLLINO_R9,
CONTROLLINO_R10,
CONTROLLINO_R11,
CONTROLLINO_R12,
CONTROLLINO_R13,
CONTROLLINO_R14,
CONTROLLINO_R15 };
/* The input pin devID array */
//static byte Settings::digitINdevID[IN_PINS] = { 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30 };
/* the output pin devID array */
//static byte Settings::digitOUTdevID[OUT_PINS] = { 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70 };
/* the shadeID array (numbers must be consecutive) */
static byte Settings::shadeIDs[SHADES] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 };
/* the lightID array (numbers must be consecutive) */
static byte Settings::lightIDs[LIGHTS] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37};
/* 1-wire pin number */
static byte Settings::oneWirePin = 20;
#elif defined(CONTROLLINO_MAXI)
static byte Settings::digitIN[IN_PINS] = { CONTROLLINO_A0,
CONTROLLINO_A1,
CONTROLLINO_A2,
CONTROLLINO_A3,
CONTROLLINO_A4,
CONTROLLINO_A5,
CONTROLLINO_A6,
CONTROLLINO_A7,
CONTROLLINO_A8,
CONTROLLINO_A9,
CONTROLLINO_IN0,
CONTROLLINO_IN1,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN,
CONTROLLINO_DUMMY_PIN };
/* The output pin array */
static byte Settings::digitOUT[OUT_PINS] = { CONTROLLINO_D0,
CONTROLLINO_D1,
CONTROLLINO_D2,
CONTROLLINO_D3,
CONTROLLINO_D4,
CONTROLLINO_D5,
CONTROLLINO_D6,
CONTROLLINO_D7,
CONTROLLINO_D8,
CONTROLLINO_D9,
CONTROLLINO_D10,
CONTROLLINO_D11,
CONTROLLINO_R0,
CONTROLLINO_R1,
CONTROLLINO_R2,
CONTROLLINO_R3,
CONTROLLINO_R4,
CONTROLLINO_R5,
CONTROLLINO_R6,
CONTROLLINO_R7,
CONTROLLINO_R8,
CONTROLLINO_R9 };
/* the shadeID array (numbers must be consecutive) */
static byte Settings::shadeIDs[SHADES] = { 1, 2, 3, 4, 5, 6 };
/* the lightID array (numbers must be consecutive) */
static byte Settings::lightIDs[LIGHTS] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22 };
/* 1-wire pin number */
static byte Settings::oneWirePin = 20;
#elif defined(CONTROLLINO_MAXI_AUTOMATION)
static byte Settings::digitIN[IN_PINS] = { CONTROLLINO_A0,
CONTROLLINO_A1,
CONTROLLINO_A2,
CONTROLLINO_A3,
CONTROLLINO_A4,
CONTROLLINO_A5,
CONTROLLINO_A6,
CONTROLLINO_A7 };
/* The output pin array */
static byte Settings::digitOUT[OUT_PINS] = { CONTROLLINO_D0,
CONTROLLINO_D1,
CONTROLLINO_D2,
CONTROLLINO_D3,
CONTROLLINO_D4,
CONTROLLINO_D5,
CONTROLLINO_D6,
CONTROLLINO_D7 };
/* the shadeID array (numbers must be consecutive) */
static byte Settings::shadeIDs[SHADES] = { 1, 2, 3, 4 };
/* the lightID array (numbers must be consecutive) */
static byte Settings::lightIDs[LIGHTS] = { 1, 2, 3, 4, 5, 6, 7, 8 };
/* 1-wire pin number */
static byte Settings::oneWirePin = 20;
#elif defined(ARDUINO_AVR_MEGA2560)
static byte Settings::digitIN[IN_PINS] = { 3,
5,
6,
7,
8,
9,
14,
15,
16,
17,
18,
19,
20,
21,
22,
23,
24,
25,
26,
27,
28,
29,
30,
31,
32,
33,
34 };
/* The output pin array */
static byte Settings::digitOUT[OUT_PINS] = { 38,
39,
40,
41,
42,
43,
44,
45,
46,
47,
48,
49,
50,
51,
52,
53,
54,
55,
56,
57,
58,
59,
60,
61,
62,
63,
64 };
/* The input pin devID array */
//static byte Settings::digitINdevID[IN_PINS] = { 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 };
/* the output pin devID array */
//static byte Settings::digitOUTdevID[OUT_PINS] = { 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61 };
/* the shadeID array (numbers must be consecutive) */
static byte Settings::shadeIDs[SHADES] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 };
/* the lightID array (numbers must be consecutive) */
static byte Settings::lightIDs[LIGHTS] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28 };
/* 1-wire pin number */
static byte Settings::oneWirePin = 2;
#else
#error "Unsupported board"
#endif
static bool Settings::getLow() {
if (Settings::relaysNC)
return LOW;
else
return HIGH;
}
static bool Settings::getHigh() {
if (Settings::relaysNC)
return HIGH;
else
return LOW;
}
static byte Settings::getLastLightDevID() {
return lightIDs[LIGHTS - 1];
}
static byte Settings::getLightOutPin(byte lightID) {
return Settings::digitOUT[(lightID - 1)];
}
static byte Settings::getLightInPin(byte lightID) {
return Settings::digitIN[(lightID - 1)];
}
static byte Settings::getShadeOutPinUp(byte shadeID) {
return Settings::digitOUT[(shadeID - 1) * 2];
}
static byte Settings::getShadeInPinUp(byte shadeID) {
return Settings::digitIN[(shadeID - 1) * 2];
}
static byte Settings::getShadeOutPinDown(byte shadeID) {
return Settings::digitOUT[((shadeID - 1) * 2) + 1];
}
static byte Settings::getShadeInPinDown(byte shadeID) {
return Settings::digitIN[((shadeID - 1) * 2) + 1];
}
static void Settings::setInPinMode(uint8_t pin) {
#if defined(CONTROLLINO_MEGA)
pinMode(pin, INPUT);
#elif defined(CONTROLLINO_MAXI)
pinMode(pin, INPUT);
#elif defined(CONTROLLINO_MAXI_AUTOMATION)
pinMode(pin, INPUT);
#elif defined(ARDUINO_AVR_MEGA2560)
pinMode(pin, INPUT_PULLUP);
#endif
}
static int Settings::getInputPinValue(uint8_t pin) {
#if defined(CONTROLLINO_MEGA)
if (pin != CONTROLLINO_DUMMY_PIN) {
return digitalRead(pin);
} else {
return LOW;
}
#elif defined(CONTROLLINO_MAXI)
if (pin != CONTROLLINO_DUMMY_PIN) {
return digitalRead(pin);
} else {
return LOW;
}
#elif defined(CONTROLLINO_MAXI_AUTOMATION)
return digitalRead(pin);
#elif defined(ARDUINO_AVR_MEGA2560)
int pinValue;
pinValue = digitalRead(pin);
if (pinValue == LOW) {
return HIGH;
} else {
return LOW;
}
#endif
}
static void Settings::setOutputPinValue(uint8_t pin, uint8_t value) {
#if defined(CONTROLLINO_MEGA)
digitalWrite(pin, value);
#elif defined(CONTROLLINO_MAXI)
digitalWrite(pin, value);
#elif defined(CONTROLLINO_MAXI_AUTOMATION)
digitalWrite(pin, value);
#elif defined(ARDUINO_AVR_MEGA2560)
if (value == HIGH) {
digitalWrite(pin, LOW);
} else {
digitalWrite(pin, HIGH);
}
#endif
}
static void Settings::initPlatform() {
#if defined(CONTROLLINO_MEGA)
Controllino_RTC_init(0);
//Controllino_SetTimeDate(7,4,11,19,11,00,45);
#elif defined(CONTROLLINO_MAXI)
Controllino_RTC_init(0);
#elif defined(CONTROLLINO_MAXI_AUTOMATION)
Controllino_RTC_init(0);
#elif defined(ARDUINO_AVR_MEGA2560)
/* nothing needed here */
#endif
}
static bool Settings::EEPROMIsRegistered() {
return (bool) EEPROM.read(EEPROM_IDX_REG);
}
static IPAddress Settings::EEPROMGetRaspyIP() {
byte address[4];
EEPROM.get(EEPROM_IDX_RASPYIP, address);
return address;
}
static byte Settings::EEPROMGetRaspyID() {
return EEPROM.read(EEPROM_IDX_RASPYID);
}
static byte Settings::EEPROMGetArdID() {
return EEPROM.read(EEPROM_IDX_ARDID);
}
static void Settings::EEPROMDeregister() {
EEPROM.write(EEPROM_IDX_REG, (byte) false);
}
static void Settings::EEPROMSetRaspyIP(IPAddress addr) {
EEPROM.write(EEPROM_IDX_RASPYIP, addr[0]);
EEPROM.write(EEPROM_IDX_RASPYIP + 1, addr[1]);
EEPROM.write(EEPROM_IDX_RASPYIP + 2, addr[2]);
EEPROM.write(EEPROM_IDX_RASPYIP + 3, addr[3]);
}
static void Settings::EEPROMRegister(byte ardID, byte raspyID, IPAddress addr) {
EEPROM.write(EEPROM_IDX_REG, (byte) true);
EEPROM.write(EEPROM_IDX_ARDID, ardID);
EEPROM.write(EEPROM_IDX_RASPYID, raspyID);
EEPROM.write(EEPROM_IDX_RASPYIP, addr[0]);
EEPROM.write(EEPROM_IDX_RASPYIP + 1, addr[1]);
EEPROM.write(EEPROM_IDX_RASPYIP + 2, addr[2]);
EEPROM.write(EEPROM_IDX_RASPYIP + 3, addr[3]);
}
static byte Settings::EEPROMGetMode() {
byte mode;
mode = EEPROM.read(EEPROM_IDX_MODE);
if (mode != MODE_LIGHTS && mode != MODE_SHADES) {
mode = MODE_LIGHTS;
EEPROM.write(EEPROM_IDX_MODE, mode);
Serial.print(F("Wrong value set as MODE value in EEPROM"));
}
return mode;
}
static void Settings::EEPROMSetMode(byte mode) {
EEPROM.write(EEPROM_IDX_MODE, mode);
}
/* The shadeIDs and lightIDs are used as index values for the entries in the EEPROM hence they must all start from 1 and be consecutive in order for the
EEPROM storage of individual configuration of devices to work properly */
/* The following scheme shows how the data is stored for lights:
* xx xx xx xxxxxxxx xx xxxxxxxx
* | | | | | |__ The float value factor used (not used at the moment)
* | | | | |_____ The ctrlON setting of the light (if it is subject to global ctrlON cmd) (byte)
* | | | |____ The timer value in miliseconds: (unsigned long)
* | | |_______ The sub-type of light device: lightType (byte)
* | |__________ The ON/OFF status of the light device: lightInputType (byte)
* |_____________ Status of the light (wether it is on or off)
*/
static void Settings::EEPROMSetLightCtrlON(byte devID, byte value) {
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1)); /* start address for Light data structure */
EEPROM.write(index + 7, value);
}
static byte Settings::EEPROMGetLightCtrlON(byte devID) {
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1)); /* start address for Light data structure */
byte ctrlON;
ctrlON = EEPROM.read(index + 7);
return ctrlON;
}
static void Settings::EEPROMSetLightConfig(byte devID, byte type, unsigned long timer) {
if (devID > LIGHTS) return;
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1)); /* start address for Light data structure */
EEPROM.write(index + 1, type);
EEPROMWritelong(index + 2, timer);
}
static byte Settings::EEPROMGetLightType(byte devID) {
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1)); /* start address for Light data structure */
byte type;
type = EEPROM.read(index + 1);
return type;
}
static void Settings::EEPROMSetLightType(byte devID, byte type) {
if (devID > LIGHTS) return;
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1)); /* start address for Light data structure */
EEPROM.write(index + 1, type);
}
static unsigned long Settings::EEPROMGetLightTimer(byte devID) {
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1)); /* start address for Light data structure */
unsigned long timer;
timer = EEPROMReadlong(index + 2);
return timer;
}
static void Settings::EEPROMSetLightTimer(byte devID, unsigned long timer) {
if (devID > LIGHTS) return;
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1)); /* start address for Light data structure */
EEPROMWritelong(index + 2, timer);
}
static void Settings::EEPROMSetLightStatus(byte devID, byte status) {
if (devID > LIGHTS) return;
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1)); /* start address for Light data structure */
EEPROM.write(index, status);
}
static byte Settings::EEPROMGetLightInputType(byte devID) {
if (devID > LIGHTS) return;
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1));
byte inputType;
inputType = EEPROM.read(index + 6);
return inputType;
}
static void Settings::EEPROMSetLightInputType(byte devID, byte inputType) {
if (devID > LIGHTS) return;
int index = EEPROM_IDX_LIGHTS + (EEPROM_IDX_LIGHTS_LENGTH * (devID - 1));
EEPROM.write(index + 6, inputType);
}
static unsigned long Settings::EEPROMReadlong(unsigned long address) {
unsigned long value;
long four = EEPROM.read(address);
long three = EEPROM.read(address + 1);
long two = EEPROM.read(address + 2);
long one = EEPROM.read(address + 3);
value = ((four << 0) & 0xFF) + ((three << 8) & 0xFFFF) + ((two << 16) & 0xFFFFFF) + ((one << 24) & 0xFFFFFFFF);
return value;
}
static void Settings::EEPROMWritelong(int address, unsigned long value) {
byte four = (value & 0xFF);
byte three = ((value >> 8) & 0xFF);
byte two = ((value >> 16) & 0xFF);
byte one = ((value >> 24) & 0xFF);
EEPROM.write(address, four);
EEPROM.write(address + 1, three);
EEPROM.write(address + 2, two);
EEPROM.write(address + 3, one);
}
static int Settings::EEPROMReadInt(int address) {
byte byte1 = EEPROM.read(address);
byte byte2 = EEPROM.read(address + 1);
return (byte1 << 8) + byte2;
}
static void Settings::EEPROMWriteInt(int address, int value) {
byte byte1 = value >> 8;
byte byte2 = value & 0xFF;
EEPROM.write(address, byte1);
EEPROM.write(address + 1, byte2);
}
static void Settings::EEPROMSetLightCentral(byte mode) {
EEPROM.write(EEPROM_IDX_CENT_CTRL, mode);
}
static byte Settings::EEPROMGetLightCentral() {
byte mode;
mode = EEPROM.read(EEPROM_IDX_CENT_CTRL);
return mode;
}
/* The shadeIDs and lightIDs are used as index values for the entries in the EEPROM hence they must all start from 1 and be consecutive in order for the
EEPROM storage of individual configuration of devices to work properly */
/* The following scheme shows how the data is stored (for a shade type device):
* xxxx xx xx xx xx xx xxxx
* | | | | | | |__________ The tile timer value (int)
* | | | | | |__________ The position timer value (byte)
* | | | | |__________ The shade device type: (byte) [reserved for future]
* | | | |_________ flags field (byte) -------------------\
* | | |__________ reached position (byte) |
* | |__________ The Tilt position of shade device: (byte) |
* |____ The Position of the shade (current state): (int) |
* |
* Flags: <----------------------------------------------------/
* xxxx xxxx
* |
* |______________ sync (1)/unsync (0) indication
*
*/
static void Settings::EEPROMSetShadeSyncFlag(byte devID) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
byte flags;
flags = EEPROM.read(index + 4);
flags = SET_BIT(flags, 7);
EEPROM.write(index + 4, flags);
}
static bool Settings::EEPROMGetShadeSyncFlag(byte devID) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
byte unsyncFlag = 0;
byte flags;
flags = EEPROM.read(index + 4);
unsyncFlag = GET_BIT(flags, 7);
return (bool) unsyncFlag;
}
static void Settings::EEPROMClearShadeSyncFlag(byte devID) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
byte flags;
flags = EEPROM.read(index + 4);
flags = CLEAR_BIT(flags, 7);
EEPROM.write(index + 4, flags);
}
static void Settings::EEPROMSetShadePosition(byte devID, int position) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
EEPROMWriteInt(index, position);
}
static int Settings::EEPROMGetShadePosition(byte devID) {
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
int position;
position = EEPROMReadInt(index);
return position;
}
static void Settings::EEPROMSetShadeReachedPosition(byte devID, byte reachedPosition) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
EEPROM.write(index + 3, reachedPosition);
}
static byte Settings::EEPROMGetShadeReachedPosition(byte devID) {
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
int reachedPosition;
reachedPosition = EEPROM.read(index + 3);
return reachedPosition;
}
static void Settings::EEPROMSetShadeTilt(byte devID, byte tilt) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
EEPROM.write(index + 2, tilt);
}
static byte Settings::EEPROMGetShadeTilt(byte devID) {
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
byte tilt;
tilt = EEPROM.read(index + 2);
return tilt;
}
static void Settings::EEPROMSetShadeType(byte devID, byte type) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
EEPROM.write(index + 5, type);
}
static void Settings::EEPROMSetShadeTiltTimer(byte devID, int timer) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
EEPROMWriteInt(index + 7, timer);
}
static void Settings::EEPROMSetShadePosTimer(byte devID, byte timer) {
if (devID > SHADES) return;
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
EEPROM.write(index + 6, timer);
}
static byte Settings::EEPROMGetShadeType(byte devID) {
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
byte type;
type = EEPROM.read(index + 5);
return type;
}
static int Settings::EEPROMGetShadeTiltTimer(byte devID) {
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
int timer;
timer = EEPROMReadInt(index + 7);
return timer;
}
static byte Settings::EEPROMGetShadePosTimer(byte devID) {
int index = EEPROM_IDX_SHADES + (EEPROM_IDX_SHADES_LENGTH * (devID - 1));
byte timer;
timer = EEPROM.read(index + 6);
return timer;
}
/* ----- network ----- */
static void Settings::EEPROMSetMAC(byte *mac) {
for (byte i = 0; i < 6; i++) {
EEPROM.write(EEPROM_IDX_MAC + i, mac[i]);
}
}
static void Settings::EEPROMGetMAC(byte *mac) {
for (byte i = 0; i < 6; i++) {
mac[i] = EEPROM.read(EEPROM_IDX_MAC + i);
}
}
static void Settings::EEPROMSetUseDefMAC(byte status) {
EEPROM.write(EEPROM_IDX_USE_DEF_MAC, status);
}
static byte Settings::EEPROMGetUseDefMAC() {
return EEPROM.read(EEPROM_IDX_USE_DEF_MAC);
}
static void Settings::EEPROMSetUID() {
EEPROMWritelong(EEPROM_IDX_UID, EEPROM_UID);
}
static bool Settings::EEPROMIsUIDSet() {
unsigned long uid;
uid = EEPROMReadlong(EEPROM_IDX_UID);
Serial.print("UID: ");
Serial.println(uid);
if (uid == EEPROM_UID) {
return true;
} else {
return false;
}
}
static void Settings::EEPROMRaze() {
uint16_t len;
len = EEPROM.length();
for (int i = 0; i < len; i++) {
if (i == EEPROM_IDX_ARDID) {
EEPROM.write(EEPROM_IDX_ARDID, 0);
} else if (i == EEPROM_IDX_REG) {
EEPROM.write(EEPROM_IDX_REG, (byte) false);
} else {
EEPROM.write(i, 255);
}
}
/* set all EEPROM Shades as unsynced and default timers */
for (int i = 0; i < SHADES; i++) {
EEPROMClearShadeSyncFlag(Settings::shadeIDs[i]);
EEPROMSetShadeTiltTimer(Settings::shadeIDs[i], EEPROM_SHADE_DEFAULT_TILT_TIMER);
EEPROMSetShadePosTimer(Settings::shadeIDs[i], EEPROM_SHADE_DEFAULT_POSITION_TIMER);
}
/* set all EEPROM Lights default values */
for (int i = 0; i < LIGHTS; i++) {
EEPROMSetLightTimer(Settings::lightIDs[i], EEPROM_DIGITOUT_DEFAULT_TIMER);
}
}
static bool Settings::EEPROMClearUID() {
unsigned long uid;
uid = 0;
EEPROMWritelong(EEPROM_IDX_UID, uid);
}
static byte Settings::SDCardInit() {
#if defined(CONTROLLINO_MEGA)
/* no support on Controllino for SD Card */
#elif defined(CONTROLLINO_MAXI)
/* no support on Controllino for SD Card */
#elif defined(CONTROLLINO_MAXI_AUTOMATION)
/* no support on Controllino for SD Card */
#elif defined(ARDUINO_AVR_MEGA2560)
pinMode(SD_ARD_MEGA_CS, OUTPUT); /* set the Select pin */
digitalWrite(SD_ARD_MEGA_CS, LOW); /* set the SD Card CS to LOW to for the time of SD initialization */
delay(500);
if (!SD.begin(SD_ARD_MEGA_CS))
{
Serial.println(F("Comm issue with SD Card ctrl. No SD Card available."));
digitalWrite(SD_ARD_MEGA_CS, HIGH);
return SD_INIT_NOHW;
}
if (!SD.exists("MAIN.CSS")) {
Serial.println(F("ERROR - Can't find MAIN.CSS file!"));
digitalWrite(SD_ARD_MEGA_CS, HIGH);
return SD_INIT_NOFILE;
} else {
if (!SD.exists("MAIN.JS")) {
Serial.println(F("ERROR - Can't find MAIN.JS file!"));
digitalWrite(SD_ARD_MEGA_CS, HIGH);
return SD_INIT_NOFILE;
} else {
Serial.println(F("SUCCESS - All files present!"));
digitalWrite(SD_ARD_MEGA_CS, HIGH);
return SD_INIT_SUCCESS;
}
}
#endif
}
static File Settings::SDCardFileOpen(char *filename) {
File file;
file = SD.open(filename);
return file;
}
static void Settings::SDCardFileClose(File file) {
file.close();
}
static byte Settings::getOneWirePin() {
return ONE_WIRE_PIN;
}