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6.4.1.2 Rewrite Switch driver 

6.4.1.2 20181228
 * Change switch driver making it modular and introduce input filter (#4665, #4724)
 * Add define DS18B20_INTERNAL_PULLUP to select internal input pullup when only one DS18B20 sensor is connected eliminating external resistor (#4738)
 * Add variable %timestamp% to rules (#4749)
This commit is contained in:
Theo Arends 2018-12-28 16:35:19 +01:00
parent 17bc48add6
commit 5a44b12870
6 changed files with 221 additions and 171 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

7
sonoff/_changelog.ino
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@ -1,4 +1,9 @@
/* 6.4.1.1 20181224 /* 6.4.1.2 20181228
* Change switch driver making it modular and introduce input filter (#4665, #4724)
* Add define DS18B20_INTERNAL_PULLUP to select internal input pullup when only one DS18B20 sensor is connected eliminating external resistor (#4738)
* Add variable %timestamp% to rules (#4749)
*
* 6.4.1.1 20181224
* Fix most compiler warnings * Fix most compiler warnings
* Change switch input detection by optimizing switch debounce (#4724) * Change switch input detection by optimizing switch debounce (#4724)
* *

173
sonoff/sonoff.ino
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@ -109,7 +109,6 @@ unsigned long pulse_timer[MAX_PULSETIMERS] = { 0 }; // Power off timer
unsigned long blink_timer = 0; // Power cycle timer unsigned long blink_timer = 0; // Power cycle timer
unsigned long backlog_delay = 0; // Command backlog delay unsigned long backlog_delay = 0; // Command backlog delay
unsigned long button_debounce = 0; // Button debounce timer unsigned long button_debounce = 0; // Button debounce timer
unsigned long switch_debounce = 0; // Switch debounce timer
power_t power = 0; // Current copy of Settings.power power_t power = 0; // Current copy of Settings.power
power_t blink_power; // Blink power state power_t blink_power; // Blink power state
power_t blink_mask = 0; // Blink relay active mask power_t blink_mask = 0; // Blink relay active mask
@ -127,7 +126,6 @@ int blinks = 201; // Number of LED blinks
uint32_t uptime = 0; // Counting every second until 4294967295 = 130 year uint32_t uptime = 0; // Counting every second until 4294967295 = 130 year
uint32_t loop_load_avg = 0; // Indicative loop load average uint32_t loop_load_avg = 0; // Indicative loop load average
uint32_t global_update = 0; // Timestamp of last global temperature and humidity update uint32_t global_update = 0; // Timestamp of last global temperature and humidity update
uint32_t switch_change[MAX_SWITCHES]; // Timestamp of last switch change
float global_temperature = 0; // Provide a global temperature to be used by some sensors float global_temperature = 0; // Provide a global temperature to be used by some sensors
float global_humidity = 0; // Provide a global humidity to be used by some sensors float global_humidity = 0; // Provide a global humidity to be used by some sensors
char *ota_url; // OTA url string pointer char *ota_url; // OTA url string pointer
@ -137,7 +135,6 @@ uint16_t blink_counter = 0; // Number of blink cycles
uint16_t seriallog_timer = 0; // Timer to disable Seriallog uint16_t seriallog_timer = 0; // Timer to disable Seriallog
uint16_t syslog_timer = 0; // Timer to re-enable syslog_level uint16_t syslog_timer = 0; // Timer to re-enable syslog_level
uint16_t holdbutton[MAX_KEYS] = { 0 }; // Timer for button hold uint16_t holdbutton[MAX_KEYS] = { 0 }; // Timer for button hold
uint16_t switch_no_pullup = 0; // Switch pull-up bitmask flags
int16_t save_data_counter; // Counter and flag for config save to Flash int16_t save_data_counter; // Counter and flag for config save to Flash
RulesBitfield rules_flag; // Rule state flags (16 bits) RulesBitfield rules_flag; // Rule state flags (16 bits)
uint8_t serial_local = 0; // Handle serial locally; uint8_t serial_local = 0; // Handle serial locally;
@ -155,9 +152,6 @@ uint8_t blinkspeed = 1; // LED blink rate
uint8_t lastbutton[MAX_KEYS] = { NOT_PRESSED, NOT_PRESSED, NOT_PRESSED, NOT_PRESSED }; // Last button states uint8_t lastbutton[MAX_KEYS] = { NOT_PRESSED, NOT_PRESSED, NOT_PRESSED, NOT_PRESSED }; // Last button states
uint8_t multiwindow[MAX_KEYS] = { 0 }; // Max time between button presses to record press count uint8_t multiwindow[MAX_KEYS] = { 0 }; // Max time between button presses to record press count
uint8_t multipress[MAX_KEYS] = { 0 }; // Number of button presses within multiwindow uint8_t multipress[MAX_KEYS] = { 0 }; // Number of button presses within multiwindow
uint8_t lastwallswitch[MAX_SWITCHES]; // Last wall switch states
uint8_t holdwallswitch[MAX_SWITCHES] = { 0 }; // Timer for wallswitch push button hold
uint8_t virtualswitch[MAX_SWITCHES]; // Virtual switch states
uint8_t pin[GPIO_MAX]; // Possible pin configurations uint8_t pin[GPIO_MAX]; // Possible pin configurations
uint8_t led_inverted = 0; // LED inverted flag (1 = (0 = On, 1 = Off)) uint8_t led_inverted = 0; // LED inverted flag (1 = (0 = On, 1 = Off))
uint8_t pwm_inverted = 0; // PWM inverted flag (1 = inverted) uint8_t pwm_inverted = 0; // PWM inverted flag (1 = inverted)
@ -1163,7 +1157,6 @@ void MqttDataHandler(char* topic, byte* data, unsigned int data_len)
else if ((CMND_SWITCHMODE == command_code) && (index > 0) && (index <= MAX_SWITCHES)) { else if ((CMND_SWITCHMODE == command_code) && (index > 0) && (index <= MAX_SWITCHES)) {
if ((payload >= 0) && (payload < MAX_SWITCH_OPTION)) { if ((payload >= 0) && (payload < MAX_SWITCH_OPTION)) {
Settings.switchmode[index -1] = payload; Settings.switchmode[index -1] = payload;
GpioSwitchPinMode(index -1);
} }
snprintf_P(mqtt_data, sizeof(mqtt_data), S_JSON_COMMAND_INDEX_NVALUE, command, index, Settings.switchmode[index-1]); snprintf_P(mqtt_data, sizeof(mqtt_data), S_JSON_COMMAND_INDEX_NVALUE, command, index, Settings.switchmode[index-1]);
} }
@ -1648,7 +1641,7 @@ boolean MqttShowSensor(void)
if (pin[GPIO_SWT1 +i] < 99) { if (pin[GPIO_SWT1 +i] < 99) {
#endif // USE_TM1638 #endif // USE_TM1638
boolean swm = ((FOLLOW_INV == Settings.switchmode[i]) || (PUSHBUTTON_INV == Settings.switchmode[i]) || (PUSHBUTTONHOLD_INV == Settings.switchmode[i])); boolean swm = ((FOLLOW_INV == Settings.switchmode[i]) || (PUSHBUTTON_INV == Settings.switchmode[i]) || (PUSHBUTTONHOLD_INV == Settings.switchmode[i]));
snprintf_P(mqtt_data, sizeof(mqtt_data), PSTR("%s,\"" D_JSON_SWITCH "%d\":\"%s\""), mqtt_data, i +1, GetStateText(swm ^ lastwallswitch[i])); snprintf_P(mqtt_data, sizeof(mqtt_data), PSTR("%s,\"" D_JSON_SWITCH "%d\":\"%s\""), mqtt_data, i +1, GetStateText(swm ^ SwitchLastState(i)));
} }
} }
XsnsCall(FUNC_JSON_APPEND); XsnsCall(FUNC_JSON_APPEND);
@ -1888,93 +1881,6 @@ void ButtonHandler(void)
} }
} }
/*********************************************************************************************\
* Switch handler
\*********************************************************************************************/
void SwitchHandler(byte mode)
{
uint8_t button = NOT_PRESSED;
uint8_t switchflag;
uint16_t loops_per_second = 1000 / Settings.switch_debounce;
for (byte i = 0; i < MAX_SWITCHES; i++) {
if (((pin[GPIO_SWT1 +i] < 99) && (TimePassedSince(switch_change[i]) > Settings.switch_debounce)) || (mode)) {
if (holdwallswitch[i]) {
holdwallswitch[i]--;
if (0 == holdwallswitch[i]) {
SendKey(1, i +1, 3); // Execute command via MQTT
}
}
if (mode) {
button = virtualswitch[i];
} else {
if (!((uptime < 4) && (0 == pin[GPIO_SWT1 +i]))) { // Block GPIO0 for 4 seconds after poweron to workaround Wemos D1 RTS circuit
button = digitalRead(pin[GPIO_SWT1 +i]);
}
}
if (button != lastwallswitch[i]) {
switchflag = 3;
switch (Settings.switchmode[i]) {
case TOGGLE:
switchflag = 2; // Toggle
break;
case FOLLOW:
switchflag = button &1; // Follow wall switch state
break;
case FOLLOW_INV:
switchflag = ~button &1; // Follow inverted wall switch state
break;
case PUSHBUTTON:
if ((PRESSED == button) && (NOT_PRESSED == lastwallswitch[i])) {
switchflag = 2; // Toggle with pushbutton to Gnd
}
break;
case PUSHBUTTON_INV:
if ((NOT_PRESSED == button) && (PRESSED == lastwallswitch[i])) {
switchflag = 2; // Toggle with releasing pushbutton from Gnd
}
break;
case PUSHBUTTON_TOGGLE:
if (button != lastwallswitch[i]) {
switchflag = 2; // Toggle with any pushbutton change
}
break;
case PUSHBUTTONHOLD:
if ((PRESSED == button) && (NOT_PRESSED == lastwallswitch[i])) {
holdwallswitch[i] = loops_per_second * Settings.param[P_HOLD_TIME] / 10;
}
if ((NOT_PRESSED == button) && (PRESSED == lastwallswitch[i]) && (holdwallswitch[i])) {
holdwallswitch[i] = 0;
switchflag = 2; // Toggle with pushbutton to Gnd
}
break;
case PUSHBUTTONHOLD_INV:
if ((NOT_PRESSED == button) && (PRESSED == lastwallswitch[i])) {
holdwallswitch[i] = loops_per_second * Settings.param[P_HOLD_TIME] / 10;
}
if ((PRESSED == button) && (NOT_PRESSED == lastwallswitch[i]) && (holdwallswitch[i])) {
holdwallswitch[i] = 0;
switchflag = 2; // Toggle with pushbutton to Gnd
}
break;
}
if (switchflag < 3) {
if (!SendKey(1, i +1, switchflag)) { // Execute command via MQTT
ExecuteCommandPower(i +1, switchflag, SRC_SWITCH); // Execute command internally (if i < devices_present)
}
}
lastwallswitch[i] = button;
}
}
}
}
/*********************************************************************************************\ /*********************************************************************************************\
* State loops * State loops
\*********************************************************************************************/ \*********************************************************************************************/
@ -2404,65 +2310,9 @@ void SerialInput(void)
serial_in_byte_counter = 0; serial_in_byte_counter = 0;
} }
} }
/********************************************************************************************/ /********************************************************************************************/
void SwitchChange(byte index)
{
switch_change[index] = millis();
}
void SwitchChange1(void)
{
SwitchChange(0);
}
void SwitchChange2(void)
{
SwitchChange(1);
}
void SwitchChange3(void)
{
SwitchChange(2);
}
void SwitchChange4(void)
{
SwitchChange(3);
}
void SwitchChange5(void)
{
SwitchChange(4);
}
void SwitchChange6(void)
{
SwitchChange(5);
}
void SwitchChange7(void)
{
SwitchChange(6);
}
void SwitchChange8(void)
{
SwitchChange(7);
}
void GpioSwitchPinMode(uint8_t index)
{
if ((pin[GPIO_SWT1 +index] < 99) && (index < MAX_SWITCHES)) {
pinMode(pin[GPIO_SWT1 +index], (16 == pin[GPIO_SWT1 +index]) ? INPUT_PULLDOWN_16 : bitRead(switch_no_pullup, index) ? INPUT : INPUT_PULLUP);
typedef void (*function)(void) ;
function switch_callbacks[MAX_SWITCHES] = { SwitchChange1, SwitchChange2, SwitchChange3, SwitchChange4, SwitchChange5, SwitchChange6, SwitchChange7, SwitchChange8 };
detachInterrupt(pin[GPIO_SWT1 +index]);
attachInterrupt(pin[GPIO_SWT1 +index], switch_callbacks[index], CHANGE);
}
}
void GpioInit(void) void GpioInit(void)
{ {
uint8_t mpin; uint8_t mpin;
@ -2499,7 +2349,7 @@ void GpioInit(void)
if (mpin) { if (mpin) {
if ((mpin >= GPIO_SWT1_NP) && (mpin < (GPIO_SWT1_NP + MAX_SWITCHES))) { if ((mpin >= GPIO_SWT1_NP) && (mpin < (GPIO_SWT1_NP + MAX_SWITCHES))) {
bitSet(switch_no_pullup, mpin - GPIO_SWT1_NP); SwitchPullupFlag(mpin - GPIO_SWT1_NP);
mpin -= (GPIO_SWT1_NP - GPIO_SWT1); mpin -= (GPIO_SWT1_NP - GPIO_SWT1);
} }
else if ((mpin >= GPIO_KEY1_NP) && (mpin < (GPIO_KEY1_NP + MAX_KEYS))) { else if ((mpin >= GPIO_KEY1_NP) && (mpin < (GPIO_KEY1_NP + MAX_KEYS))) {
@ -2631,14 +2481,8 @@ void GpioInit(void)
digitalWrite(pin[GPIO_LED1 +i], bitRead(led_inverted, i)); digitalWrite(pin[GPIO_LED1 +i], bitRead(led_inverted, i));
} }
} }
for (byte i = 0; i < MAX_SWITCHES; i++) {
lastwallswitch[i] = 1; // Init global to virtual switch state; SwitchInit();
if (pin[GPIO_SWT1 +i] < 99) {
GpioSwitchPinMode(i);
lastwallswitch[i] = digitalRead(pin[GPIO_SWT1 +i]); // Set global now so doesn't change the saved power state on first switch check
}
virtualswitch[i] = lastwallswitch[i];
}
#ifdef USE_WS2812 #ifdef USE_WS2812
if (!light_type && (pin[GPIO_WS2812] < 99)) { // RGB led if (!light_type && (pin[GPIO_WS2812] < 99)) { // RGB led
@ -2826,10 +2670,9 @@ void loop(void)
SetNextTimeInterval(button_debounce, Settings.button_debounce); SetNextTimeInterval(button_debounce, Settings.button_debounce);
ButtonHandler(); ButtonHandler();
} }
if (TimeReached(switch_debounce)) {
SetNextTimeInterval(switch_debounce, Settings.switch_debounce); SwitchLoop();
SwitchHandler(0);
}
if (TimeReached(state_50msecond)) { if (TimeReached(state_50msecond)) {
SetNextTimeInterval(state_50msecond, 50); SetNextTimeInterval(state_50msecond, 50);
XdrvCall(FUNC_EVERY_50_MSECOND); XdrvCall(FUNC_EVERY_50_MSECOND);

2
sonoff/sonoff_version.h
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@ -20,7 +20,7 @@
#ifndef _SONOFF_VERSION_H_ #ifndef _SONOFF_VERSION_H_
#define _SONOFF_VERSION_H_ #define _SONOFF_VERSION_H_
#define VERSION 0x06040101 #define VERSION 0x06040102
#define D_PROGRAMNAME "Sonoff-Tasmota" #define D_PROGRAMNAME "Sonoff-Tasmota"
#define D_AUTHOR "Theo Arends" #define D_AUTHOR "Theo Arends"

202
sonoff/support_switch.ino Normal file
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@ -0,0 +1,202 @@
/*
support_switch.ino - switch support for Sonoff-Tasmota
Copyright (C) 2018 Theo Arends
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#define SWITCH_V2
#ifdef SWITCH_V2
/*********************************************************************************************\
* Switch support with input filter
*
* Inspired by (https://github.com/OLIMEX/olimex-iot-firmware-esp8266/blob/master/olimex/user/user_switch2.c)
\*********************************************************************************************/
#define SWITCH_STATE_FILTER 5
#include <Ticker.h>
Ticker TickerSwitch;
unsigned long switch_debounce = 0; // Switch debounce timer
uint16_t switch_no_pullup = 0; // Switch pull-up bitmask flags
uint8_t switch_state_buf[MAX_SWITCHES] = { SWITCH_STATE_FILTER / 2 };
uint8_t lastwallswitch[MAX_SWITCHES]; // Last wall switch states
uint8_t holdwallswitch[MAX_SWITCHES] = { 0 }; // Timer for wallswitch push button hold
uint8_t switch_virtual[MAX_SWITCHES]; // Virtual switch states
uint8_t switches_found = 0;
/********************************************************************************************/
void SwitchPullupFlag(uint16 switch_bit)
{
bitSet(switch_no_pullup, switch_bit);
}
uint8_t SwitchLastState(uint8_t index)
{
return lastwallswitch[index];
}
void SwitchSetVirtual(uint8_t index, uint8_t state)
{
switch_virtual[index] = state;
}
uint8_t SwitchGetVirtual(uint8_t index)
{
return switch_virtual[index];
}
/*********************************************************************************************/
void SwitchProbe(void)
{
for (byte i = 0; i < MAX_SWITCHES; i++) {
if (pin[GPIO_SWT1 +i] < 99) {
if (!((uptime < 4) && (0 == pin[GPIO_SWT1 +i]))) { // Block GPIO0 for 4 seconds after poweron to workaround Wemos D1 RTS circuit
// Olimex user_switch2.c code to fix 50Hz induced pulses
if (1 == digitalRead(pin[GPIO_SWT1 +i])) {
if (switch_state_buf[i] < SWITCH_STATE_FILTER) {
switch_state_buf[i]++;
if (SWITCH_STATE_FILTER == switch_state_buf[i]) {
switch_virtual[i] = 1;
}
}
} else {
if (switch_state_buf[i] > 0) {
switch_state_buf[i]--;
if (0 == switch_state_buf[i]) {
switch_virtual[i] = 0;
}
}
}
}
}
}
TickerSwitch.attach_ms(10, SwitchProbe); // Re-arm as core 2.3.0 does only support ONCE mode
}
void SwitchInit(void)
{
switches_found = 0;
for (byte i = 0; i < MAX_SWITCHES; i++) {
lastwallswitch[i] = 1; // Init global to virtual switch state;
if (pin[GPIO_SWT1 +i] < 99) {
switches_found++;
pinMode(pin[GPIO_SWT1 +i], (16 == pin[GPIO_SWT1 +i]) ? INPUT_PULLDOWN_16 : bitRead(switch_no_pullup, i) ? INPUT : INPUT_PULLUP);
lastwallswitch[i] = digitalRead(pin[GPIO_SWT1 +i]); // Set global now so doesn't change the saved power state on first switch check
}
switch_virtual[i] = lastwallswitch[i];
}
if (switches_found) { TickerSwitch.attach_ms(10, SwitchProbe); }
}
/*********************************************************************************************\
* Switch handler
\*********************************************************************************************/
void SwitchHandler(byte mode)
{
uint8_t button = NOT_PRESSED;
uint8_t switchflag;
uint16_t loops_per_second = 1000 / Settings.switch_debounce;
for (byte i = 0; i < MAX_SWITCHES; i++) {
if ((pin[GPIO_SWT1 +i] < 99) || (mode)) {
if (holdwallswitch[i]) {
holdwallswitch[i]--;
if (0 == holdwallswitch[i]) {
SendKey(1, i +1, 3); // Execute command via MQTT
}
}
button = switch_virtual[i];
// enum SwitchModeOptions {TOGGLE, FOLLOW, FOLLOW_INV, PUSHBUTTON, PUSHBUTTON_INV, PUSHBUTTONHOLD, PUSHBUTTONHOLD_INV, PUSHBUTTON_TOGGLE, MAX_SWITCH_OPTION};
if (button != lastwallswitch[i]) {
switchflag = 3;
switch (Settings.switchmode[i]) {
case TOGGLE:
switchflag = 2; // Toggle
break;
case FOLLOW:
switchflag = button &1; // Follow wall switch state
break;
case FOLLOW_INV:
switchflag = ~button &1; // Follow inverted wall switch state
break;
case PUSHBUTTON:
if ((PRESSED == button) && (NOT_PRESSED == lastwallswitch[i])) {
switchflag = 2; // Toggle with pushbutton to Gnd
}
break;
case PUSHBUTTON_INV:
if ((NOT_PRESSED == button) && (PRESSED == lastwallswitch[i])) {
switchflag = 2; // Toggle with releasing pushbutton from Gnd
}
break;
case PUSHBUTTON_TOGGLE:
if (button != lastwallswitch[i]) {
switchflag = 2; // Toggle with any pushbutton change
}
break;
case PUSHBUTTONHOLD:
if ((PRESSED == button) && (NOT_PRESSED == lastwallswitch[i])) {
holdwallswitch[i] = loops_per_second * Settings.param[P_HOLD_TIME] / 10;
}
if ((NOT_PRESSED == button) && (PRESSED == lastwallswitch[i]) && (holdwallswitch[i])) {
holdwallswitch[i] = 0;
switchflag = 2; // Toggle with pushbutton to Gnd
}
break;
case PUSHBUTTONHOLD_INV:
if ((NOT_PRESSED == button) && (PRESSED == lastwallswitch[i])) {
holdwallswitch[i] = loops_per_second * Settings.param[P_HOLD_TIME] / 10;
}
if ((PRESSED == button) && (NOT_PRESSED == lastwallswitch[i]) && (holdwallswitch[i])) {
holdwallswitch[i] = 0;
switchflag = 2; // Toggle with pushbutton to Gnd
}
break;
}
if (switchflag < 3) {
if (!SendKey(1, i +1, switchflag)) { // Execute command via MQTT
ExecuteCommandPower(i +1, switchflag, SRC_SWITCH); // Execute command internally (if i < devices_present)
}
}
lastwallswitch[i] = button;
}
}
}
}
void SwitchLoop(void)
{
if (switches_found) {
if (TimeReached(switch_debounce)) {
SetNextTimeInterval(switch_debounce, Settings.switch_debounce);
SwitchHandler(0);
}
}
}
#endif // SWITCH_V2

2
sonoff/xdrv_10_rules.ino
View File

@ -410,7 +410,7 @@ void RulesEvery50ms(void)
if (pin[GPIO_SWT1 +i] < 99) { if (pin[GPIO_SWT1 +i] < 99) {
#endif // USE_TM1638 #endif // USE_TM1638
boolean swm = ((FOLLOW_INV == Settings.switchmode[i]) || (PUSHBUTTON_INV == Settings.switchmode[i]) || (PUSHBUTTONHOLD_INV == Settings.switchmode[i])); boolean swm = ((FOLLOW_INV == Settings.switchmode[i]) || (PUSHBUTTON_INV == Settings.switchmode[i]) || (PUSHBUTTONHOLD_INV == Settings.switchmode[i]));
snprintf_P(json_event, sizeof(json_event), PSTR("{\"" D_JSON_SWITCH "%d\":{\"Boot\":%d}}"), i +1, (swm ^ lastwallswitch[i])); snprintf_P(json_event, sizeof(json_event), PSTR("{\"" D_JSON_SWITCH "%d\":{\"Boot\":%d}}"), i +1, (swm ^ SwitchLastState(i)));
RulesProcessEvent(json_event); RulesProcessEvent(json_event);
} }
} }

4
sonoff/xsns_28_tm1638.ino
View File

@ -176,8 +176,8 @@ void TmLoop(void)
if (tm1638_state) { if (tm1638_state) {
byte buttons = Tm1638GetButtons(); byte buttons = Tm1638GetButtons();
for (byte i = 0; i < MAX_SWITCHES; i++) { for (byte i = 0; i < MAX_SWITCHES; i++) {
virtualswitch[i] = (buttons &1) ^1; SwitchSetVirtual(i, (buttons &1) ^1);
byte color = (virtualswitch[i]) ? TM1638_COLOR_NONE : TM1638_COLOR_RED; byte color = (SwitchGetVirtual(i)) ? TM1638_COLOR_NONE : TM1638_COLOR_RED;
Tm1638SetLED(color, i); Tm1638SetLED(color, i);
buttons >>= 1; buttons >>= 1;
} }