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/* SPDX-License-Identifier: GPL-2.0-only */
#ifndef __SRC_INCLUDE_GPIO_H__
#define __SRC_INCLUDE_GPIO_H__
#include <soc/gpio.h> /* IWYU pragma: export */
#ifndef __ASSEMBLER__ /* __ASSEMBLER__ also covers __ACPI__ case */
#include <types.h>
/* <soc/gpio.h> must typedef a gpio_t that fits in 32 bits. */
_Static_assert(sizeof(gpio_t) <= sizeof(u32), "gpio_t doesn't fit in lb_gpio");
/* The following functions must be implemented by SoC/board code. */
int gpio_get(gpio_t gpio);
void gpio_set(gpio_t gpio, int value);
void gpio_input_pulldown(gpio_t gpio);
void gpio_input_pullup(gpio_t gpio);
void gpio_input(gpio_t gpio);
void gpio_output(gpio_t gpio, int value);
uint32_t _gpio_base3_value(const gpio_t gpio[], int num_gpio, int binary_first);
/*
* This function may be implemented by SoC/board code to provide
* a mapping from a GPIO pin to controller by returning the ACPI
* path for the controller that owns this GPIO.
*
* If not implemented the default handler will return NULL.
*/
const char *gpio_acpi_path(gpio_t gpio);
/*
* This function may be implemented by SoC/board code to provide
* a mapping from the internal representation of a GPIO to the 16bit
* value used in an ACPI GPIO pin table entry.
*
* If not implemented by the SOC the default handler will return 0
* because the underlying type of gpio_t is unknown.
*/
uint16_t gpio_acpi_pin(gpio_t gpio);
/*
* Read the value presented by the set of GPIOs, when each pin is interpreted
* as a base-2 digit (LOW = 0, HIGH = 1).
*
* gpio[]: pin positions to read. gpio[0] is less significant than gpio[1].
* num_gpio: number of pins to read.
*
* There are also pulldown and pullup variants which default each gpio to
* be configured with an internal pulldown and pullup, respectively.
*/
uint32_t gpio_base2_value(const gpio_t gpio[], int num_gpio);
uint32_t gpio_pulldown_base2_value(const gpio_t gpio[], int num_gpio);
uint32_t gpio_pullup_base2_value(const gpio_t gpio[], int num_gpio);
/*
* Read the value presented by the set of GPIOs, when each pin is interpreted
* as a base-3 digit (LOW = 0, HIGH = 1, Z/floating = 2).
* Example: X1 = Z, X2 = 1 -> gpio_base3_value({GPIO(X1), GPIO(X2)}) = 5
* BASE3() from <base3.h> can generate numbers to compare the result to.
*
* gpio[]: pin positions to read. gpio[0] is less significant than gpio[1].
* num_gpio: number of pins to read.
*/
static inline uint32_t gpio_base3_value(const gpio_t gpio[], int num_gpio)
{
return _gpio_base3_value(gpio, num_gpio, 0);
}
/*
* Read the value presented by the set of GPIOs, when each pin is interpreted
* as a base-3 digit (LOW = 0, HIGH = 1, Z/floating = 2) in a non-standard
* ternary number system where the first 2^n natural numbers are represented
* as they would be in a binary system (without any Z digits), and the following
* 3^n-2^n numbers use the remaining ternary representations in the normal
* ternary system order (skipping the values that were already used up).
* This is useful for boards which initially used a binary board ID and later
* decided to switch to tri-state after some revisions have already been built.
* Example: For num_gpio = 2 we get the following representation:
*
* Number X1 X0
* 0 0 0
* 1 0 1
* 2 1 0
* 3 1 1 // Start counting ternaries back at 0 after this
* 4 0 2 // Skipping 00 and 01 which are already used up
* 5 1 2 // Skipping 10 and 11 which are already used up
* 6 2 0
* 7 2 1
* 8 2 2
*
* gpio[]: pin positions to read. gpio[0] is less significant than gpio[1].
* num_gpio: number of pins to read.
*/
static inline uint32_t gpio_binary_first_base3_value(const gpio_t gpio[],
int num_gpio)
{
return _gpio_base3_value(gpio, num_gpio, 1);
}
#endif /* !__ASSEMBLER__ */
#endif /* __SRC_INCLUDE_GPIO_H__ */
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