flipperzero-firmware/wiki/fw/api/HAL-API.md

# GPIO

GPIO defined as struct `GpioPin`.

GPIO functions:

```C
// Init GPIO
void gpio_init(GpioPin* gpio, GpioMode mode);

typedef enum { GpioModeInput, GpioModeOutput, GpioModeOpenDrain } GpioMode;

// write value to GPIO
void gpio_write(GpioPin* gpio, bool state);

// read value from GPIO, f = LOW, t = HIGH
bool gpio_read(GpioPin* gpio);
```

When application is exited, system place pin to Z-state by calling `gpio_disable`.

```C
// put GPIO to Z-state (used for restore pin state on app exit)
void gpio_disable(ValueMutex* gpio_mutex) {
    GpioPin* gpio = acquire_mutex(gpio_mutex, 0);
    gpio_init(gpio, GpioModeInput);
    release_mutex(gpio_mutex, gpio);
}
```

Available GPIO stored in FURI as `ValueMutex<GpioPin*>`.

```C
inline static ValueMutex* open_gpio_mutex(const char* name) {
    ValueMutex* gpio_mutex = (ValueMutex*)furi_open(name);
    if(gpio_mutex != NULL) flapp_on_exit(gpio_disable, gpio_mutex);

    return gpio_mutex;
}

// helper
inline static GpioPin* open_gpio(const char* name) {
    ValueMutex* gpio_mutex = open_gpio(name);
    return (GpioPin*)acquire_mutex(gpio_mutex, 0);
}
```

## Available GPIO (target F2)

* PA4
* PA5
* PA6
* PA7
* PB2
* PC3
* PC0
* PC1
* PB6
* PB7
* PA13
* PA14
* RFID_PULL
* IR_TX
* IBUTTON
* VIBRO

## Usage example

```C
void gpio_example() {
    GpioPin* pin = open_gpio("PB6");

    if(pin == NULL) {
        printf("pin not available\n");
        return;
    }

    gpio_init(pin, GpioModeOutput);

    while(1) {
        gpio_write(pin, true);
        delay(100);
        gpio_write(pin, false);
        delay(100);
    }
}
```

# PWM

PWM defined as `PwmPin`. To set PWM channel:

```C
void pwm_set(PwmPin* pwm, float value, float freq);
```

When application is exited, system disable pwm by calling `pwm_disable`.

```C
// put GPIO to Z-state (used for restore pin state on app exit)
void pwm_disable(ValueMutex* pwm_mutex) {
    PwmPin* pwm = acquire_mutex(pwm_mutex, 0);
    pwm_set(pwm, 0., 0.);
    release_mutex(pwm_mutex, pwm);
}
```

Available PWM stored in FURI as `ValueMutex<PwmPin*>`.

```C
inline static ValueMutex* open_pwm_mutex(const char* name) {
    ValueMutex* pwm_mutex = (ValueMutex*)furi_open(name);
    if(pwm_mutex != NULL) flapp_on_exit(pwm_disable, pwm_mutex);

    return pwm_mutex;
}

// helper
inline static PwmPin* open_pwm(const char* name) {
    ValueMutex* pwm_mutex = open_gpio(name);
    return (PwmPin*)acquire_mutex(pwm_mutex, 0);
}
```

## Available PWM (target F2)

* SPEAKER
* RFID_OUT

## Usage example

```C
void sound_example() {
    PwmPin* speaker = open_pwm("SPEAKER");

    if(speaker == NULL) {
        printf("speaker not available\n");
        return;
    }

    while(1) {
        pwm_set(speaker, 1000., 0.1);
        delay(2);
        pwm_set(speaker, 110., 0.5);
        delay(198);
        pwm_set(speaker, 330., 0.5);
        delay(200);
    }
}
```

# ADC

Coming soon...

# I2C

Coming soon...
Core api concept (#144) * add input debounce code from old fw * exampl of input api * change input API to get/release * revert input API to read * pointer instead of instance * add input API description * add display API * rewrite display names * migrate to valuemanager * add LED API * add closing brakets * add sound api * fix led api * basic api * rename API pages * change pubsub implementation * move FURI AC -> flapp, add valuemutex example, add valuemanager implementation * pubsub usage example * user led example * update example * simplify input * add composed display * add SPI/GPIO and CC1101 bus * change cc1101 api * spi api and devices * spi api and devices * move SPI to page, add GPIO * not block pin open * backlight API and more * add minunit tests * fix logging * ignore unexisting time service on embedded targets * fix warning, issue with printf * Deprecate furi_open and furi_close (#167) Rename existing furi_open and furi_close to deprecated version * add exitcode * migrate to printf * indicate test by leds * add testing description * rename furi.h * wip basic api * add valuemutex, pubsub, split files * add value expanders * value mutex realization and tests * valuemutex test added to makefile * do not build unimplemented files * fix build furmware target f2 * redesigned minunit tests to allow testing in separate files * test file for valuemutex minunit testing * minunit partial test valuemutex * local cmsis_os2 mutex bindings * implement furi open/create, tests * migrate concurrent_access to ValueMutex * add spi header * Lib: add mlib submodule. Co-authored-by: rusdacent <rusdacentx0x08@gmail.com> Co-authored-by: DrZlo13 <who.just.the.doctor@gmail.com> 2020-10-13 08:22:43 +00:00			`# GPIO`

			GPIO defined as struct `GpioPin`.

			`GPIO functions:`

			```C
			`// Init GPIO`
			`void gpio_init(GpioPin* gpio, GpioMode mode);`

			`typedef enum { GpioModeInput, GpioModeOutput, GpioModeOpenDrain } GpioMode;`

			`// write value to GPIO`
			`void gpio_write(GpioPin* gpio, bool state);`

			`// read value from GPIO, f = LOW, t = HIGH`
			`bool gpio_read(GpioPin* gpio);`
			```

			When application is exited, system place pin to Z-state by calling `gpio_disable`.

			```C
			`// put GPIO to Z-state (used for restore pin state on app exit)`
			`void gpio_disable(ValueMutex* gpio_mutex) {`
			`GpioPin* gpio = acquire_mutex(gpio_mutex, 0);`
			`gpio_init(gpio, GpioModeInput);`
			`release_mutex(gpio_mutex, gpio);`
			`}`
			```

			Available GPIO stored in FURI as `ValueMutex<GpioPin*>`.

			```C
			`inline static ValueMutex* open_gpio_mutex(const char* name) {`
			`ValueMutex* gpio_mutex = (ValueMutex*)furi_open(name);`
			`if(gpio_mutex != NULL) flapp_on_exit(gpio_disable, gpio_mutex);`

			`return gpio_mutex;`
			`}`

			`// helper`
			`inline static GpioPin* open_gpio(const char* name) {`
			`ValueMutex* gpio_mutex = open_gpio(name);`
			`return (GpioPin*)acquire_mutex(gpio_mutex, 0);`
			`}`
			```

			`## Available GPIO (target F2)`

			`* PA4`
			`* PA5`
			`* PA6`
			`* PA7`
			`* PB2`
			`* PC3`
			`* PC0`
			`* PC1`
			`* PB6`
			`* PB7`
			`* PA13`
			`* PA14`
			`* RFID_PULL`
			`* IR_TX`
			`* IBUTTON`
			`* VIBRO`

			`## Usage example`

			```C
			`void gpio_example() {`
			`GpioPin* pin = open_gpio("PB6");`

			`if(pin == NULL) {`
			`printf("pin not available\n");`
			`return;`
			`}`

			`gpio_init(pin, GpioModeOutput);`

			`while(1) {`
			`gpio_write(pin, true);`
			`delay(100);`
			`gpio_write(pin, false);`
			`delay(100);`
			`}`
			`}`
			```

			`# PWM`

			PWM defined as `PwmPin`. To set PWM channel:

			```C
			`void pwm_set(PwmPin* pwm, float value, float freq);`
			```

			When application is exited, system disable pwm by calling `pwm_disable`.

			```C
			`// put GPIO to Z-state (used for restore pin state on app exit)`
			`void pwm_disable(ValueMutex* pwm_mutex) {`
			`PwmPin* pwm = acquire_mutex(pwm_mutex, 0);`
			`pwm_set(pwm, 0., 0.);`
			`release_mutex(pwm_mutex, pwm);`
			`}`
			```

			Available PWM stored in FURI as `ValueMutex<PwmPin*>`.

			```C
			`inline static ValueMutex* open_pwm_mutex(const char* name) {`
			`ValueMutex* pwm_mutex = (ValueMutex*)furi_open(name);`
			`if(pwm_mutex != NULL) flapp_on_exit(pwm_disable, pwm_mutex);`

			`return pwm_mutex;`
			`}`

			`// helper`
			`inline static PwmPin* open_pwm(const char* name) {`
			`ValueMutex* pwm_mutex = open_gpio(name);`
			`return (PwmPin*)acquire_mutex(pwm_mutex, 0);`
			`}`
			```

			`## Available PWM (target F2)`

			`* SPEAKER`
			`* RFID_OUT`

			`## Usage example`

			```C
			`void sound_example() {`
			`PwmPin* speaker = open_pwm("SPEAKER");`

			`if(speaker == NULL) {`
			`printf("speaker not available\n");`
			`return;`
			`}`

			`while(1) {`
			`pwm_set(speaker, 1000., 0.1);`
			`delay(2);`
			`pwm_set(speaker, 110., 0.5);`
			`delay(198);`
			`pwm_set(speaker, 330., 0.5);`
			`delay(200);`
			`}`
			`}`
			```

			`# ADC`

			`Coming soon...`

			`# I2C`

			`Coming soon...`