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Rework gpios

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This commit is contained in:
fvanroie 2021-05-15 12:39:10 +02:00
parent d42749703e
commit 859a111d9e
2 changed files with 255 additions and 170 deletions
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293
src/sys/gpio/hasp_gpio.cpp
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@ -13,8 +13,8 @@
#endif
#ifdef ARDUINO
#include "AceButton.h"
using namespace ace_button;
ButtonConfig buttonConfig; // Clicks, double-clicks and long presses
ButtonConfig switchConfig; // Clicks only
@ -36,16 +36,11 @@ ButtonConfig switchConfig; // Clicks only
hasp_gpio_config_t gpioConfig[HASP_NUM_GPIO_CONFIG] = {
// {2, 8, INPUT, LOW}, {3, 9, OUTPUT, LOW}, {4, 10, INPUT, HIGH}, {5, 11, OUTPUT, LOW}, {6, 12, INPUT, LOW},
};
uint8_t pwm_channel = 1; // Backlight has 0
static inline void gpio_update_group(uint8_t group, lv_obj_t* obj, int32_t val, int32_t min, int32_t max)
static inline void gpio_update_group(uint8_t group, lv_obj_t* obj, bool power, int32_t val, int32_t min, int32_t max)
{
hasp_update_value_t value = {
.min = min,
.max = max,
.val = val,
.obj = obj,
.group = group,
};
hasp_update_value_t value = {.obj = obj, .group = group, .min = min, .max = max, .val = val, .power = power};
dispatch_normalized_group_values(value);
}
@ -53,7 +48,8 @@ static inline void gpio_update_group(uint8_t group, lv_obj_t* obj, int32_t val,
#include "driver/uart.h"
#include <driver/dac.h>
volatile bool touchdetected = false;
volatile bool touchdetected = false;
RTC_DATA_ATTR int recordCounter = 0;
void gotTouch()
{
@ -95,7 +91,7 @@ static void gpio_event_handler(AceButton* button, uint8_t eventType, uint8_t but
bool state = false;
switch(eventType) {
case AceButton::kEventPressed:
if(gpioConfig[btnid].type == HASP_GPIO_SWITCH) {
if(gpioConfig[btnid].type != hasp_gpio_type_t::BUTTON) {
eventid = HASP_EVENT_ON;
} else {
eventid = HASP_EVENT_DOWN;
@ -118,7 +114,7 @@ static void gpio_event_handler(AceButton* button, uint8_t eventType, uint8_t but
// state = true; // do not repeat DOWN + LONG + HOLD
// break;
case AceButton::kEventReleased:
if(gpioConfig[btnid].type == HASP_GPIO_SWITCH) {
if(gpioConfig[btnid].type != hasp_gpio_type_t::BUTTON) {
eventid = HASP_EVENT_OFF;
} else {
eventid = HASP_EVENT_RELEASE;
@ -128,11 +124,11 @@ static void gpio_event_handler(AceButton* button, uint8_t eventType, uint8_t but
eventid = HASP_EVENT_LOST;
}
event_gpio_input(gpioConfig[btnid].pin, gpioConfig[btnid].group, eventid);
event_gpio_input(gpioConfig[btnid].pin, eventid);
// update objects and gpios in this group
if(gpioConfig[btnid].group && eventid != HASP_EVENT_LONG) // do not repeat DOWN + LONG
gpio_update_group(gpioConfig[btnid].group, NULL, state, HASP_EVENT_OFF, HASP_EVENT_ON);
gpio_update_group(gpioConfig[btnid].group, NULL, gpioConfig[btnid].power, state, HASP_EVENT_OFF, HASP_EVENT_ON);
}
/* ********************************* GPIO Setup *************************************** */
@ -191,64 +187,75 @@ static void gpio_setup_pin(uint8_t index)
}
uint8_t input_mode;
bool default_state = gpio->inverted ? LOW : HIGH; // default pullup
switch(gpio->gpio_function) {
case OUTPUT:
case hasp_gpio_function_t::OUTPUT_PIN:
input_mode = OUTPUT;
break;
case INPUT:
case hasp_gpio_function_t::EXTERNAL_PULLDOWN:
default_state = !default_state; // not pullup
case hasp_gpio_function_t::EXTERNAL_PULLUP:
input_mode = INPUT;
break;
#ifndef ARDUINO_ARCH_ESP8266
case INPUT_PULLDOWN:
input_mode = INPUT_PULLDOWN;
case hasp_gpio_function_t::INTERNAL_PULLDOWN:
default_state = !default_state; // not pullup
input_mode = INPUT_PULLDOWN;
break;
#endif
case hasp_gpio_function_t::INTERNAL_PULLUP:
default:
input_mode = INPUT_PULLUP;
}
gpio->max = 255;
ButtonConfig* config = &buttonConfig; // Ddefault pushbutton
gpio->power = 1; // on by default, value is set to 0
gpio->max = 255;
switch(gpio->type) {
case HASP_GPIO_SWITCH:
case hasp_gpio_type_t::SWITCH:
case hasp_gpio_type_t::BATTERY... hasp_gpio_type_t::WINDOW:
if(gpio->btn) delete gpio->btn;
gpio->btn = new AceButton(&switchConfig, gpio->pin, HIGH, index);
gpio->btn = new AceButton(&switchConfig, gpio->pin, default_state, index);
pinMode(gpio->pin, INPUT_PULLUP);
gpio->max = 0;
break;
case HASP_GPIO_BUTTON:
case hasp_gpio_type_t::BUTTON:
if(gpio->btn) delete gpio->btn;
gpio->btn = new AceButton(&buttonConfig, gpio->pin, HIGH, index);
gpio->btn = new AceButton(&buttonConfig, gpio->pin, default_state, index);
pinMode(gpio->pin, INPUT_PULLUP);
gpio->max = 0;
break;
case HASP_GPIO_TOUCH:
case hasp_gpio_type_t::TOUCH:
if(gpio->btn) delete gpio->btn;
gpio->btn = new AceButton(&touchConfig, gpio->pin, HIGH, index);
gpio->max = 0;
// touchAttachInterrupt(gpio->pin, gotTouch, 33);
break;
case HASP_GPIO_RELAY:
case hasp_gpio_type_t::POWER_RELAY:
case hasp_gpio_type_t::LIGHT_RELAY:
pinMode(gpio->pin, OUTPUT);
gpio->max = 1; // on-off
break;
case HASP_GPIO_PWM:
case hasp_gpio_type_t::PWM:
gpio->max = 4095;
case HASP_GPIO_ALL_LEDS:
// case HASP_GPIO_BACKLIGHT:
case hasp_gpio_type_t::LED... hasp_gpio_type_t::LED_W:
// case hasp_gpio_type_t::BACKLIGHT:
pinMode(gpio->pin, OUTPUT);
#if defined(ARDUINO_ARCH_ESP32)
// configure LED PWM functionalitites
ledcSetup(gpio->group, 20000, 12);
// attach the channel to the GPIO to be controlled
ledcAttachPin(gpio->pin, gpio->group);
if(pwm_channel < 16) {
// configure LED PWM functionalitites
ledcSetup(pwm_channel, 20000, 12);
// attach the channel to the GPIO to be controlled
ledcAttachPin(gpio->pin, pwm_channel);
gpio->channel = pwm_channel++;
} else {
LOG_ERROR(TAG_GPIO, F("Too many PWM channels defined"));
}
#endif
break;
case HASP_GPIO_DAC:
case hasp_gpio_type_t::DAC:
#if defined(ARDUINO_ARCH_ESP32)
gpio_num_t pin;
if(dac_pad_get_io_num(DAC_CHANNEL_1, &pin) == ESP_OK)
@ -258,11 +265,13 @@ static void gpio_setup_pin(uint8_t index)
#endif
break;
case HASP_GPIO_SERIAL_DIMMER: {
case hasp_gpio_type_t::SERIAL_DIMMER:
case hasp_gpio_type_t::SERIAL_DIMMER_AU:
case hasp_gpio_type_t::SERIAL_DIMMER_EU: {
const char command[9] = "\xEF\x01\x4D\xA3"; // Start Lanbon Dimmer
#if defined(ARDUINO_ARCH_ESP32)
Serial1.begin(115200UL, SERIAL_8N1, UART_PIN_NO_CHANGE, gpio->pin, true,
2000); // true = EU, false = AU
Serial1.begin(115200UL, SERIAL_8N1, UART_PIN_NO_CHANGE, gpio->pin,
gpio->type == hasp_gpio_type_t::SERIAL_DIMMER_EU); // true = EU, false = AU
Serial1.flush();
delay(20);
Serial1.print(" ");
@ -273,7 +282,7 @@ static void gpio_setup_pin(uint8_t index)
break;
}
case HASP_GPIO_FREE:
case hasp_gpio_type_t::FREE:
return;
default:
@ -285,6 +294,7 @@ static void gpio_setup_pin(uint8_t index)
void gpioSetup()
{
LOG_INFO(TAG_GPIO, F(D_SERVICE_STARTING));
LOG_WARNING(TAG_GPIO, F("Reboot counter %d"), recordCounter++);
aceButtonSetup();
@ -307,23 +317,55 @@ IRAM_ATTR void gpioLoop(void)
void gpioSetup(void)
{
gpioSavePinConfig(0, 3, HASP_GPIO_RELAY, 0, -1);
gpioSavePinConfig(1, 4, HASP_GPIO_RELAY, 0, -1);
gpioSavePinConfig(2, 13, HASP_GPIO_LED, 0, -1);
gpioSavePinConfig(3, 14, HASP_GPIO_DAC, 0, -1);
gpioSavePinConfig(0, 3, hasp_gpio_type_t::RELAY, 0, -1, false);
gpioSavePinConfig(1, 4, hasp_gpio_type_t::RELAY, 0, -1, false);
gpioSavePinConfig(2, 13, hasp_gpio_type_t::LED, 0, -1, false);
gpioSavePinConfig(3, 14, hasp_gpio_type_t::DAC, 0, -1, false);
}
IRAM_ATTR void gpioLoop(void)
{}
#endif // ARDUINO
static inline bool gpio_is_input(hasp_gpio_config_t* gpio)
{
return (gpio->type != hasp_gpio_type_t::USER) && (gpio->type >= 0x80);
}
static inline bool gpio_is_output(hasp_gpio_config_t* gpio)
{
return (gpio->type > hasp_gpio_type_t::USED) && (gpio->type < 0x80);
}
/* ********************************* State Setters *************************************** */
bool gpio_get_value(uint8_t pin, uint16_t& val)
bool gpio_get_pin_state(uint8_t pin, bool& power, int32_t& val)
{
for(uint8_t i = 0; i < HASP_NUM_GPIO_CONFIG; i++) {
if(gpioConfig[i].pin == pin && gpio_is_output(&gpioConfig[i])) {
power = gpioConfig[i].power;
val = gpioConfig[i].val;
return true;
}
}
return false;
}
void gpio_output_state(hasp_gpio_config_t* gpio)
{
char payload[32];
char topic[12];
snprintf_P(topic, sizeof(topic), PSTR("output%d"), gpio->pin);
snprintf_P(payload, sizeof(payload), PSTR("{\"state\":%d,\"val\":%d}"), gpio->power, gpio->val);
dispatch_state_subtopic(topic, payload);
}
bool gpio_output_pin_state(uint8_t pin)
{
for(uint8_t i = 0; i < HASP_NUM_GPIO_CONFIG; i++) {
if(gpioConfig[i].pin == pin && gpioConfigInUse(i)) {
val = gpioConfig[i].val;
gpio_output_state(&gpioConfig[i]);
return true;
}
}
@ -348,10 +390,11 @@ static inline bool gpio_set_analog_value(hasp_gpio_config_t* gpio)
else if(gpio->max == 4095)
val = gpio->val;
if(!gpio->power) val = 0;
if(gpio->inverted) val = 4095 - val;
ledcWrite(gpio->group, val); // 12 bits
return true; // sent
ledcWrite(gpio->channel, val); // 12 bits
return true; // sent
#elif defined(ARDUINO_ARCH_ESP8266)
@ -360,6 +403,7 @@ static inline bool gpio_set_analog_value(hasp_gpio_config_t* gpio)
else if(gpio->max == 4095)
val = gpio->val >> 2;
if(!gpio->power) val = 0;
if(gpio->inverted) val = 1023 - val;
analogWrite(gpio->pin, val); // 10 bits
@ -372,8 +416,13 @@ static inline bool gpio_set_analog_value(hasp_gpio_config_t* gpio)
static inline bool gpio_set_serial_dimmer(hasp_gpio_config_t* gpio)
{
uint16_t val = gpio_limit(gpio->val, 0, 255);
if(!gpio->power) val = 0;
if(gpio->inverted) val = 255 - val;
char command[5] = "\xEF\x02\x00\xED";
command[2] = (uint8_t)map(gpio->val, 0, 255, 0, 100);
command[2] = (uint8_t)map(val, 0, 255, 0, 100);
command[3] ^= command[2];
#if defined(ARDUINO_ARCH_ESP32)
@ -389,7 +438,12 @@ static inline bool gpio_set_serial_dimmer(hasp_gpio_config_t* gpio)
static inline bool gpio_set_dac_value(hasp_gpio_config_t* gpio)
{
#ifdef ARDUINO_ARCH_ESP32
uint16_t val = gpio_limit(gpio->val, 0, 255);
gpio_num_t pin;
if(!gpio->power) val = 0;
if(gpio->inverted) val = 255 - val;
if(dac_pad_get_io_num(DAC_CHANNEL_1, &pin) == ESP_OK && gpio->pin == pin)
dac_output_voltage(DAC_CHANNEL_1, gpio->val);
else if(dac_pad_get_io_num(DAC_CHANNEL_2, &pin) == ESP_OK && gpio->pin == pin)
@ -415,23 +469,30 @@ bool gpio_get_pin_config(uint8_t pin, hasp_gpio_config_t** gpio)
// Update the actual value of one pin, does NOT update group members
// The value must be normalized first
static bool gpio_set_output_value(hasp_gpio_config_t* gpio, uint16_t val)
static bool gpio_set_output_value(hasp_gpio_config_t* gpio, bool power, uint16_t val)
{
gpio->val = gpio_limit(val, 0, gpio->max);
// if val is 0, then set power to 0
gpio->power = val == 0 ? 0 : power;
// Only update the current value if power set to 1, otherwise retain previous value
if(power) gpio->val = gpio_limit(val, 0, gpio->max);
switch(gpio->type) {
case HASP_GPIO_RELAY:
digitalWrite(gpio->pin, gpio->inverted ? !gpio->val : gpio->val);
case hasp_gpio_type_t::POWER_RELAY:
case hasp_gpio_type_t::LIGHT_RELAY:
digitalWrite(gpio->pin, power ? (gpio->inverted ? !gpio->val : gpio->val) : 0);
return true;
case HASP_GPIO_ALL_LEDS:
case HASP_GPIO_PWM:
case hasp_gpio_type_t::LED... hasp_gpio_type_t::LED_W:
case hasp_gpio_type_t::PWM:
return gpio_set_analog_value(gpio);
case HASP_GPIO_DAC:
case hasp_gpio_type_t::DAC:
return gpio_set_dac_value(gpio);
case HASP_GPIO_SERIAL_DIMMER:
case hasp_gpio_type_t::SERIAL_DIMMER:
case hasp_gpio_type_t::SERIAL_DIMMER_AU:
case hasp_gpio_type_t::SERIAL_DIMMER_EU:
return gpio_set_serial_dimmer(gpio);
default:
@ -441,41 +502,37 @@ static bool gpio_set_output_value(hasp_gpio_config_t* gpio, uint16_t val)
}
// Update the normalized value of one pin
void gpio_set_normalized_value(hasp_gpio_config_t* gpio, int32_t val, int32_t min, int32_t max)
static void gpio_set_normalized_value(hasp_gpio_config_t* gpio, hasp_update_value_t& value)
{
if(min != 0 || max != gpio->max) { // do we need to recalculate?
if(min == max) {
int32_t val = value.val;
if(value.min != 0 || value.max != gpio->max) { // do we need to recalculate?
if(value.min == value.max) {
LOG_ERROR(TAG_GPIO, F("Invalid value range"));
return;
}
switch(gpio->type) {
case HASP_GPIO_RELAY:
val = val > min ? HIGH : LOW;
case hasp_gpio_type_t::POWER_RELAY:
case hasp_gpio_type_t::LIGHT_RELAY:
val = val > value.min ? HIGH : LOW;
break;
case HASP_GPIO_ALL_LEDS:
case HASP_GPIO_DAC:
case HASP_GPIO_PWM:
case HASP_GPIO_SERIAL_DIMMER:
val = map(val, min, max, 0, gpio->max);
case hasp_gpio_type_t::LED... hasp_gpio_type_t::LED_W:
case hasp_gpio_type_t::DAC:
case hasp_gpio_type_t::PWM:
case hasp_gpio_type_t::SERIAL_DIMMER:
case hasp_gpio_type_t::SERIAL_DIMMER_AU:
case hasp_gpio_type_t::SERIAL_DIMMER_EU:
val = map(val, value.min, value.max, 0, gpio->max);
break;
default:
return; // invalid output type
}
}
gpio_set_output_value(gpio, val); // recalculated
}
static inline bool gpio_is_input(hasp_gpio_config_t* gpio)
{
return gpio->type == HASP_GPIO_BUTTON || gpio->type == HASP_GPIO_SWITCH || gpio->type == HASP_GPIO_TOUCH;
}
static inline bool gpio_is_output(hasp_gpio_config_t* gpio)
{
return (gpio->type != HASP_GPIO_FREE) && !gpio_is_input(gpio);
gpio_set_output_value(gpio, value.power, val); // recalculated
}
// Dispatch all group member values
@ -484,7 +541,7 @@ void gpio_output_group_values(uint8_t group)
for(uint8_t k = 0; k < HASP_NUM_GPIO_CONFIG; k++) {
hasp_gpio_config_t* gpio = &gpioConfig[k];
if(gpio->group == group && gpio_is_output(gpio)) // group members that are outputs
dispatch_output_pin_value(gpioConfig[k].pin, gpioConfig[k].val);
gpio_output_state(&gpioConfig[k]);
}
}
@ -497,7 +554,7 @@ void gpio_set_normalized_group_values(hasp_update_value_t& value)
for(uint8_t k = 0; k < HASP_NUM_GPIO_CONFIG; k++) {
hasp_gpio_config_t* gpio = &gpioConfig[k];
if(gpio->group == value.group && gpioConfigInUse(k)) // group members that are outputs
gpio_set_normalized_value(gpio, value.val, value.min, value.max);
gpio_set_normalized_value(gpio, value);
}
// Log the changed output values
@ -507,29 +564,34 @@ void gpio_set_normalized_group_values(hasp_update_value_t& value)
}
// Update the value of an output pin and its group members
bool gpio_set_pin_value(uint8_t pin, int32_t val)
bool gpio_set_pin_state(uint8_t pin, bool power, int32_t val)
{
hasp_gpio_config_t* gpio = NULL;
if(!gpio_get_pin_config(pin, &gpio) || !gpio) {
LOG_WARNING(TAG_GPIO, F(D_BULLET "Pin %d is not configured"), pin);
return false;
}
} else if(gpio_is_output(gpio)) {
if(!gpio_is_output(gpio)) {
LOG_WARNING(TAG_GPIO, F(D_BULLET "Pin %d can not be set"), pin);
if(gpio->group) gpio_output_group_values(gpio->group);
return false;
}
if(gpio->group) {
// update objects and gpios in this group
gpio_update_group(gpio->group, NULL, gpio->val, 0, gpio->max);
gpio->power = power;
gpio->val = gpio_limit(val, 0, gpio->max);
gpio_update_group(gpio->group, NULL, gpio->power, gpio->val, 0, gpio->max);
} else {
// update this gpio value only
gpio_set_output_value(gpio, val);
dispatch_output_pin_value(gpio->pin, gpio->val);
LOG_VERBOSE(TAG_GPIO, F("No Group - Pin %d = %d"), gpio->pin, gpio->val);
if(gpio_set_output_value(gpio, power, val)) {
gpio_output_state(gpio);
LOG_VERBOSE(TAG_GPIO, F("No Group - Pin %d = %d"), gpio->pin, gpio->val);
} else {
return false;
}
}
return true; // pin found and set
@ -538,38 +600,22 @@ bool gpio_set_pin_value(uint8_t pin, int32_t val)
// Updates the RGB pins directly, rgb are already normalized values
void gpio_set_moodlight(moodlight_t& moodlight)
{
uint8_t r = 0;
uint8_t g = 0;
uint8_t b = 0;
if(moodlight.power && moodlight.brightness) {
r = (moodlight.r * moodlight.brightness + 127) / 255;
g = (moodlight.g * moodlight.brightness + 127) / 255;
b = (moodlight.b * moodlight.brightness + 127) / 255;
} else {
moodlight.power = 0;
}
// RGBXX https://stackoverflow.com/questions/39949331/how-to-calculate-rgbaw-amber-white-from-rgb-for-leds
for(uint8_t i = 0; i < HASP_NUM_GPIO_CONFIG; i++) {
switch(gpioConfig[i].type) {
case HASP_GPIO_LED_R:
gpio_set_output_value(&gpioConfig[i], r);
break;
case HASP_GPIO_LED_G:
gpio_set_output_value(&gpioConfig[i], g);
break;
case HASP_GPIO_LED_B:
gpio_set_output_value(&gpioConfig[i], b);
case hasp_gpio_type_t::LED_R... hasp_gpio_type_t::LED_W:
uint8_t index = (gpioConfig[i].type - hasp_gpio_type_t::LED_R) / 2;
if(index > 4) continue;
uint8_t val = (moodlight.rgbww[index] * moodlight.brightness + 127) / 255;
gpio_set_output_value(&gpioConfig[i], moodlight.power, val);
break;
}
}
for(uint8_t i = 0; i < HASP_NUM_GPIO_CONFIG; i++) {
switch(gpioConfig[i].type) {
case HASP_GPIO_LED_B:
case HASP_GPIO_LED_G:
case HASP_GPIO_LED_R:
case hasp_gpio_type_t::LED_R... hasp_gpio_type_t::LED_W:
LOG_VERBOSE(TAG_GPIO, F(D_BULLET D_GPIO_PIN " %d => %d"), gpioConfig[i].pin, gpioConfig[i].val);
break;
}
@ -689,10 +735,10 @@ bool gpioIsSystemPin(uint8_t gpio)
return false;
}
bool gpioInUse(uint8_t gpio)
bool gpioInUse(uint8_t pin)
{
for(uint8_t i = 0; i < HASP_NUM_GPIO_CONFIG; i++) {
if((gpioConfig[i].pin == gpio) && gpioConfigInUse(i)) {
if((gpioConfig[i].pin == pin) && gpioConfigInUse(i)) {
return true; // pin matches and is in use
}
}
@ -700,7 +746,7 @@ bool gpioInUse(uint8_t gpio)
return false;
}
bool gpioSavePinConfig(uint8_t config_num, uint8_t pin, uint8_t type, uint8_t group, uint8_t pinfunc)
bool gpioSavePinConfig(uint8_t config_num, uint8_t pin, uint8_t type, uint8_t group, uint8_t pinfunc, bool inverted)
{
// TODO: Input validation
@ -713,6 +759,7 @@ bool gpioSavePinConfig(uint8_t config_num, uint8_t pin, uint8_t type, uint8_t gr
gpioConfig[config_num].type = type;
gpioConfig[config_num].group = group;
gpioConfig[config_num].gpio_function = pinfunc;
gpioConfig[config_num].inverted = inverted;
LOG_TRACE(TAG_GPIO, F("Saving Pin config #%d pin %d - type %d - group %d - func %d"), config_num, pin, type,
group, pinfunc);
return true;
@ -724,7 +771,7 @@ bool gpioSavePinConfig(uint8_t config_num, uint8_t pin, uint8_t type, uint8_t gr
bool gpioConfigInUse(uint8_t num)
{
if(num >= HASP_NUM_GPIO_CONFIG) return false;
return gpioConfig[num].type != HASP_GPIO_FREE;
return gpioConfig[num].type != hasp_gpio_type_t::FREE;
}
int8_t gpioGetFreeConfigId()
@ -746,20 +793,23 @@ void gpio_discovery(JsonArray& relay, JsonArray& led)
{
for(uint8_t i = 0; i < HASP_NUM_GPIO_CONFIG; i++) {
switch(gpioConfig[i].type) {
case HASP_GPIO_RELAY:
case hasp_gpio_type_t::LIGHT_RELAY:
case hasp_gpio_type_t::POWER_RELAY:
relay.add(gpioConfig[i].pin);
break;
case HASP_GPIO_DAC:
case HASP_GPIO_LED: // Don't include the moodlight
case HASP_GPIO_SERIAL_DIMMER:
case hasp_gpio_type_t::DAC:
case hasp_gpio_type_t::LED: // Don't include the moodlight
case hasp_gpio_type_t::SERIAL_DIMMER:
case hasp_gpio_type_t::SERIAL_DIMMER_AU:
case hasp_gpio_type_t::SERIAL_DIMMER_EU:
led.add(gpioConfig[i].pin);
break;
// pwm.add(gpioConfig[i].pin);
break;
case HASP_GPIO_FREE:
case hasp_gpio_type_t::FREE:
default:
break;
}
@ -778,7 +828,7 @@ bool gpioGetConfig(const JsonObject& settings)
for(JsonVariant v : array) {
if(i < HASP_NUM_GPIO_CONFIG) {
uint32_t cur_val = gpioConfig[i].pin | (gpioConfig[i].group << 8) | (gpioConfig[i].type << 16) |
(gpioConfig[i].gpio_function << 24);
(gpioConfig[i].gpio_function << 24) | (gpioConfig[i].inverted << 31);
LOG_INFO(TAG_GPIO, F("GPIO CONF: %d: %d <=> %d"), i, cur_val, v.as<uint32_t>());
if(cur_val != v.as<uint32_t>()) changed = true;
@ -794,7 +844,7 @@ bool gpioGetConfig(const JsonObject& settings)
array = settings[FPSTR(FP_GPIO_CONFIG)].to<JsonArray>(); // Clear JsonArray
for(uint8_t i = 0; i < HASP_NUM_GPIO_CONFIG; i++) {
uint32_t cur_val = gpioConfig[i].pin | (gpioConfig[i].group << 8) | (gpioConfig[i].type << 16) |
(gpioConfig[i].gpio_function << 24);
(gpioConfig[i].gpio_function << 24) | (gpioConfig[i].inverted << 31);
array.add(cur_val);
}
changed = true;
@ -827,13 +877,14 @@ bool gpioSetConfig(const JsonObject& settings)
if(i < HASP_NUM_GPIO_CONFIG) {
uint32_t cur_val = gpioConfig[i].pin | (gpioConfig[i].group << 8) | (gpioConfig[i].type << 16) |
(gpioConfig[i].gpio_function << 24);
(gpioConfig[i].gpio_function << 24) | (gpioConfig[i].inverted << 31);
if(cur_val != new_val) status = true;
gpioConfig[i].pin = new_val & 0xFF;
gpioConfig[i].group = new_val >> 8 & 0xFF;
gpioConfig[i].type = new_val >> 16 & 0xFF;
gpioConfig[i].gpio_function = new_val >> 24 & 0xFF;
gpioConfig[i].gpio_function = new_val >> 24 & 0x7F;
gpioConfig[i].inverted = new_val >> 31 & 0x1;
}
i++;
}

132
src/sys/gpio/hasp_gpio.h
View File

@ -17,10 +17,11 @@ extern "C" {
struct hasp_gpio_config_t
{
uint8_t gpio_function : 8; // INPUT, OUTPUT, PULLUP, etc
uint8_t pin : 8; // pin number
uint8_t group : 6; // groupid
uint8_t group : 8; // groupid
uint8_t gpio_function : 7; // INPUT, OUTPUT, PULLUP, etc
uint8_t inverted : 1;
uint8_t channel : 4; // pwmchannel
uint8_t power : 1;
uint8_t type; // switch, button, ...
uint16_t val;
@ -37,15 +38,17 @@ void gpioEvery5Seconds(void);
void gpio_set_normalized_group_values(hasp_update_value_t& value);
void gpio_output_group_values(uint8_t group);
bool gpio_get_value(uint8_t pin, uint16_t& val);
bool gpio_set_pin_value(uint8_t pin, int32_t val);
bool gpio_output_pin_state(uint8_t pin);
bool gpio_get_pin_state(uint8_t pin, bool& power, int32_t& val);
bool gpio_set_pin_state(uint8_t pin, bool power, int32_t val);
void gpio_set_moodlight(moodlight_t& moodlight);
void gpio_discovery(JsonArray& relay, JsonArray& led);
bool gpioSavePinConfig(uint8_t config_num, uint8_t pin, uint8_t type, uint8_t group, uint8_t pinfunc);
bool gpioSavePinConfig(uint8_t config_num, uint8_t pin, uint8_t type, uint8_t group, uint8_t pinfunc, bool inverted);
bool gpioIsSystemPin(uint8_t gpio);
bool gpioInUse(uint8_t gpio);
bool gpioInUse(uint8_t pin);
bool gpioConfigInUse(uint8_t num);
int8_t gpioGetFreeConfigId();
hasp_gpio_config_t gpioGetPinConfig(uint8_t num);
@ -55,49 +58,80 @@ bool gpioGetConfig(const JsonObject& settings);
bool gpioSetConfig(const JsonObject& settings);
#endif
#define HASP_GPIO_FREE 0x00
#define HASP_GPIO_USED 0x01
#define HASP_GPIO_SWITCH 0x02 // User Inputs
// #define HASP_GPIO_SWITCH_INVERTED 0x03
#define HASP_GPIO_BUTTON 0x04
// #define HASP_GPIO_BUTTON_INVERTED 0x05
#define HASP_GPIO_TOUCH 0x06
// #define HASP_GPIO_TOUCH_INVERTED 0x07
#define HASP_GPIO_COUNTER_RISE 0x10 // User Counters
// #define HASP_GPIO_COUNTER_RISE_INVERTED 0x11
#define HASP_GPIO_COUNTER_FALL 0x12
// #define HASP_GPIO_COUNTER_FALL_INVERTED 0x13
#define HASP_GPIO_COUNTER_BOTH 0x14
// #define HASP_GPIO_COUNTER_BOTH_INVERTED 0x15
#define HASP_GPIO_RELAY 0x20 // User Outputs
// #define HASP_GPIO_RELAY_INVERTED 0x21
#define HASP_GPIO_ALL_LEDS 0x22 ... 0x2F
#define HASP_GPIO_LED 0x22
// #define HASP_GPIO_LED_INVERTED 0x23
#define HASP_GPIO_LED_R 0x24
// #define HASP_GPIO_LED_R_INVERTED 0x25
#define HASP_GPIO_LED_G 0x26
// #define HASP_GPIO_LED_G_INVERTED 0x27
#define HASP_GPIO_LED_B 0x28
// #define HASP_GPIO_LED_B_INVERTED 0x29
#define HASP_GPIO_LED_W 0x2A
// #define HASP_GPIO_LED_W_INVERTED 0x2B
#define HASP_GPIO_LED_WW 0x2C
// #define HASP_GPIO_LED_WW_INVERTED 0x2D
#define HASP_GPIO_LED_CW 0x2E
// #define HASP_GPIO_LED_CW_INVERTED 0x2F
#define HASP_GPIO_PWM 0x40
// #define HASP_GPIO_PWM_INVERTED 0x41
#define HASP_GPIO_DAC 0x50
// #define HASP_GPIO_DAC_INVERTED 0x51
#define HASP_GPIO_ADC 0x52
// #define HASP_GPIO_ADC_INVERTED 0x53
#define HASP_GPIO_SERIAL_DIMMER 0x60
#define HASP_GPIO_BUZZER 0x70
// #define HASP_GPIO_BUZZER_INVERTED 0x71
#define HASP_GPIO_HAPTIC 0x72
// #define HASP_GPIO_HAPTIC_INVERTED 0x73
#define HASP_GPIO_USER 0xFF
enum hasp_gpio_function_t {
OUTPUT_PIN = 1,
INTERNAL_PULLUP = 2,
INTERNAL_PULLDOWN = 3,
EXTERNAL_PULLUP = 4,
EXTERNAL_PULLDOWN = 5
};
enum hasp_gpio_type_t {
FREE = 0x00,
USED = 0x01,
/* Outputs */
LED = 0x02,
LED_R = 0x03,
LED_G = 0x04,
LED_B = 0x05,
LED_CW = 0x06,
LED_WW = 0x07,
LED_W = 0x08,
LIGHT_RELAY = 0x0A,
POWER_RELAY = 0x0B,
SHUTTER_RELAY = 0x0C,
SHUTTER_OPEN = 0x1A,
SHUTTER_CLOSE = 0x1B,
BACKLIGHT = 0x20,
PWM = 0x21,
DAC = 0x22,
SERIAL_DIMMER = 0x30,
SERIAL_DIMMER_EU = 0x31,
SERIAL_DIMMER_AU = 0x32,
BUZZER = 0x40,
HAPTIC = 0x41,
/* Inputs */
BATTERY = 0xA1,
BATTERY_CHARGING = 0xA2,
COLD = 0xA3,
CONNECTIVITY = 0xA4,
DOOR = 0xA5,
GARAGE_DOOR = 0xA6,
GAS = 0xA7,
HEAT = 0xA8,
LIGHT = 0xA9,
LOCK = 0xAA,
MOISTURE = 0xAB,
MOTION = 0xAC,
OCCUPANCY = 0xAD,
OPENING = 0xAE,
PLUG = 0xAF,
PRESENCE = 0xB0,
PROBLEM = 0xB1,
SAFETY = 0xB2,
SMOKE = 0xB3,
SOUND = 0xB4,
VIBRATION = 0xB5,
WINDOW = 0xB6,
SWITCH = 0xC0, // Binary Sensors
BUTTON = 0xF0,
BUTTON_TOGGLE_ON = 0xF1,
BUTTON_TOGGLE_OFF = 0xF2,
BUTTON_TOGGLE_BOTH = 0xF3,
TOUCH = 0xF4,
ADC = 0xF9,
COUNTER_RISE = 0xFA, // User Counters
COUNTER_FALL = 0xFB,
COUNTER_BOTH = 0xFC,
USER = 0xFF
};
#ifdef __cplusplus
} /* extern "C" */