rt-thread/bsp/beaglebone/drivers/gpio.c

376 lines
11 KiB
C

/*
* Copyright (c) 2006-2021, RT-Thread Development Team
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 2015-06-19 ItsEddy add gpio driver support
* 2022-09-14 YangZhongQing full gpio driver support
* I referred AM335X_StarterWare_02_00_01_01
*/
#include <ctype.h>
#include <rthw.h>
#include <rtthread.h>
#include <rtdevice.h>
#include <am33xx.h>
#include <interrupt.h>
#include "gpio.h"
#ifdef RT_USING_PIN
#define reg(base) *(int*)(base)
#define GPIO_PIN_LOW (0x0)
#define GPIO_PIN_HIGH (0x1)
/* Values denoting the Interrupt Line number to be used. */
#define GPIO_INT_LINE_1 (0x0)
#define GPIO_INT_LINE_2 (0x1)
#define GPIO_REVISION (0x0)
#define GPIO_SYSCONFIG (0x10)
#define GPIO_IRQSTATUS_RAW(n) (0x24 + (n * 4))
#define GPIO_IRQSTATUS(n) (0x2C + (n * 4))
#define GPIO_IRQSTATUS_SET(n) (0x34 + (n * 4))
#define GPIO_IRQSTATUS_CLR(n) (0x3C + (n * 4))
#define GPIO_IRQWAKEN(n) (0x44 + (n * 4))
#define GPIO_SYSSTATUS (0x114)
#define GPIO_CTRL (0x130)
#define GPIO_OE (0x134)
#define GPIO_DATAIN (0x138)
#define GPIO_DATAOUT (0x13C)
#define GPIO_LEVELDETECT(n) (0x140 + (n * 4))
#define GPIO_RISINGDETECT (0x148)
#define GPIO_FALLINGDETECT (0x14C)
#define GPIO_DEBOUNCENABLE (0x150)
#define GPIO_DEBOUNCINGTIME (0x154)
#define GPIO_CLEARDATAOUT (0x190)
#define GPIO_SETDATAOUT (0x194)
static const rt_base_t GPIO_BASE[] =
{
AM33XX_GPIO_0_REGS,
AM33XX_GPIO_1_REGS,
AM33XX_GPIO_2_REGS,
AM33XX_GPIO_3_REGS
};
#define GPIO_INT0x GPIO_INT0A
#define GPIO_INT1x GPIO_INT1A
#define GPIO_INT2x GPIO_INT2A
#define GPIO_INT3x GPIO_INT3A
static const rt_uint8_t GPIO_INTx[] = {GPIO_INT0x, GPIO_INT1x, GPIO_INT2x, GPIO_INT3x};
// auto determine which int line
#define GPIO_INT0_LINE ((GPIO_INT0x == GPIO_INT0A) ? GPIO_INT_LINE_1 : GPIO_INT_LINE_2)
#define GPIO_INT1_LINE ((GPIO_INT1x == GPIO_INT1A) ? GPIO_INT_LINE_1 : GPIO_INT_LINE_2)
#define GPIO_INT2_LINE ((GPIO_INT2x == GPIO_INT2A) ? GPIO_INT_LINE_1 : GPIO_INT_LINE_2)
#define GPIO_INT3_LINE ((GPIO_INT3x == GPIO_INT3A) ? GPIO_INT_LINE_1 : GPIO_INT_LINE_2)
static const rt_uint8_t GPIO_INT_LINEx[] = {GPIO_INT0_LINE, GPIO_INT1_LINE, GPIO_INT2_LINE, GPIO_INT3_LINE};
struct am33xx_pin_irq_hdr
{
void (*hdr)(void *args);
void *args;
};
struct am33xx_gpio_irq_param
{
struct am33xx_pin_irq_hdr hdr_tab[32];
};
static struct am33xx_gpio_irq_param GPIO_PARAMx[sizeof(GPIO_BASE) / sizeof(GPIO_BASE[0])];
rt_inline void am33xx_gpio_hdr(rt_base_t base, rt_base_t int_line, void *param)
{
struct am33xx_gpio_irq_param *irq_param = param;
struct am33xx_pin_irq_hdr *irq_hdr;
int pinNumber;
rt_ubase_t irqstatus;
irqstatus = REG32(base + GPIO_IRQSTATUS(int_line));
REG32(base + GPIO_IRQSTATUS(int_line)) = irqstatus;
for (pinNumber = 0; pinNumber < sizeof(irq_param->hdr_tab); pinNumber++)
{
if (irqstatus & 0x1)
{
irq_hdr = &irq_param->hdr_tab[pinNumber];
if (irq_hdr->hdr)
irq_hdr->hdr(irq_hdr->args);
// if the last one, exit immediately
if (irqstatus == 0x1)
break;
}
irqstatus >>= 1;
}
}
static void am33xx_gpio0_isr(int vector, void *param)
{
am33xx_gpio_hdr(AM33XX_GPIO_0_REGS, GPIO_INT0_LINE, param);
}
static void am33xx_gpio1_isr(int vector, void *param)
{
am33xx_gpio_hdr(AM33XX_GPIO_1_REGS, GPIO_INT1_LINE, param);
}
static void am33xx_gpio2_isr(int vector, void *param)
{
am33xx_gpio_hdr(AM33XX_GPIO_2_REGS, GPIO_INT2_LINE, param);
}
static void am33xx_gpio3_isr(int vector, void *param)
{
am33xx_gpio_hdr(AM33XX_GPIO_3_REGS, GPIO_INT3_LINE, param);
}
static const rt_isr_handler_t GPIO_ISRx[] =
{
am33xx_gpio0_isr,
am33xx_gpio1_isr,
am33xx_gpio2_isr,
am33xx_gpio3_isr,
};
static void am33xx_pin_mode(struct rt_device *device, rt_base_t pin, rt_uint8_t mode)
{
RT_ASSERT(pin >= 0 && pin < 128);
RT_ASSERT(mode != PIN_MODE_INPUT_PULLUP); /* Mode not supported */
rt_base_t gpiox = pin >> 5;
rt_base_t pinNumber = pin & 0x1F;
if (PIN_MODE_OUTPUT == mode)
{
reg(GPIO_BASE[gpiox] + GPIO_OE) &= ~(1 << pinNumber);
}
else if (PIN_MODE_INPUT == mode)
{
reg(GPIO_BASE[gpiox] + GPIO_OE) |= (1 << pinNumber);
}
}
static void am33xx_pin_write(struct rt_device *device, rt_base_t pin, rt_uint8_t value)
{
RT_ASSERT(pin >= 0 && pin < 128);
rt_base_t gpiox = pin >> 5;
rt_base_t pinNumber = pin & 0x1F;
if (GPIO_PIN_HIGH == value)
{
reg(GPIO_BASE[gpiox] + GPIO_SETDATAOUT) = (1 << pinNumber);
}
else /* GPIO_PIN_LOW */
{
reg(GPIO_BASE[gpiox] + GPIO_CLEARDATAOUT) = (1 << pinNumber);
}
}
static rt_int8_t am33xx_pin_read(struct rt_device *device, rt_base_t pin)
{
RT_ASSERT(pin >= 0 && pin < 128);
rt_base_t gpiox = pin >> 5;
rt_base_t pinNumber = pin & 0x1F;
return reg(GPIO_BASE[gpiox] + GPIO_DATAIN) & (1 << pinNumber) ? 1 : 0;
}
static rt_err_t am33xx_pin_attach_irq(struct rt_device *device, rt_base_t pin,
rt_uint8_t mode, void (*hdr)(void *args), void *args)
{
RT_ASSERT(pin >= 0 && pin < 128);
rt_base_t gpiox = pin >> 5;
rt_base_t pinNumber = pin & 0x1F;
rt_base_t baseAdd = GPIO_BASE[gpiox];
struct am33xx_pin_irq_hdr *irq_hdr = &GPIO_PARAMx[gpiox].hdr_tab[pinNumber];
rt_base_t level;
level = rt_hw_interrupt_disable();
if (irq_hdr->hdr != RT_NULL)
{
rt_hw_interrupt_enable(level);
return -RT_EBUSY;
}
irq_hdr->hdr = hdr;
irq_hdr->args = args;
switch (mode)
{
case PIN_IRQ_MODE_RISING:
/* Enabling rising edge detect interrupt generation. */
REG32(baseAdd + GPIO_RISINGDETECT) |= (1 << pinNumber);
/* Disabling falling edge detect interrupt generation. */
REG32(baseAdd + GPIO_FALLINGDETECT) &= ~(1 << pinNumber);
/* Disabling logic LOW level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(0)) &= ~(1 << pinNumber);
/* Disabling logic HIGH level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(1)) &= ~(1 << pinNumber);
break;
case PIN_IRQ_MODE_FALLING:
/* Disabling rising edge detect interrupt generation. */
REG32(baseAdd + GPIO_RISINGDETECT) &= ~(1 << pinNumber);
/* Enabling falling edge detect interrupt generation. */
REG32(baseAdd + GPIO_FALLINGDETECT) |= (1 << pinNumber);
/* Disabling logic LOW level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(0)) &= ~(1 << pinNumber);
/* Disabling logic HIGH level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(1)) &= ~(1 << pinNumber);
break;
case PIN_IRQ_MODE_RISING_FALLING:
/* Enabling rising edge detect interrupt generation. */
REG32(baseAdd + GPIO_RISINGDETECT) |= (1 << pinNumber);
/* Enabling falling edge detect interrupt generation. */
REG32(baseAdd + GPIO_FALLINGDETECT) |= (1 << pinNumber);
/* Disabling logic LOW level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(0)) &= ~(1 << pinNumber);
/* Disabling logic HIGH level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(1)) &= ~(1 << pinNumber);
break;
case PIN_IRQ_MODE_HIGH_LEVEL:
/* Disabling logic LOW level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(0)) &= ~(1 << pinNumber);
/* Enabling logic HIGH level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(1)) |= (1 << pinNumber);
/* Disabling rising edge detect interrupt generation. */
REG32(baseAdd + GPIO_RISINGDETECT) &= ~(1 << pinNumber);
/* Disabling falling edge detect interrupt generation. */
REG32(baseAdd + GPIO_FALLINGDETECT) &= ~(1 << pinNumber);
break;
case PIN_IRQ_MODE_LOW_LEVEL:
/* Enabling logic LOW level detect interrupt geenration. */
REG32(baseAdd + GPIO_LEVELDETECT(0)) |= (1 << pinNumber);
/* Disabling logic HIGH level detect interrupt generation. */
REG32(baseAdd + GPIO_LEVELDETECT(1)) &= ~(1 << pinNumber);
/* Disabling rising edge detect interrupt generation. */
REG32(baseAdd + GPIO_RISINGDETECT) &= ~(1 << pinNumber);
/* Disabling falling edge detect interrupt generation. */
REG32(baseAdd + GPIO_FALLINGDETECT) &= ~(1 << pinNumber);
break;
}
rt_hw_interrupt_enable(level);
return 0;
}
static rt_err_t am33xx_pin_detach_irq(struct rt_device *device, rt_base_t pin)
{
RT_ASSERT(pin >= 0 && pin < 128);
rt_base_t gpiox = pin >> 5;
rt_base_t pinNumber = pin & 0x1F;
struct am33xx_pin_irq_hdr *irq_hdr = &GPIO_PARAMx[gpiox].hdr_tab[pinNumber];
rt_base_t level;
level = rt_hw_interrupt_disable();
irq_hdr->hdr = RT_NULL;
irq_hdr->args = RT_NULL;
rt_hw_interrupt_enable(level);
return 0;
}
static rt_err_t am33xx_pin_irq_enable(struct rt_device *device, rt_base_t pin, rt_uint8_t enabled)
{
RT_ASSERT(pin >= 0 && pin < 128);
rt_base_t gpiox = pin >> 5;
rt_base_t pinNumber = pin & 0x1F;
rt_base_t baseAdd = GPIO_BASE[gpiox];
rt_base_t intLine = GPIO_INT_LINEx[gpiox];
if (enabled == PIN_IRQ_ENABLE)
REG32(baseAdd + GPIO_IRQSTATUS_SET(intLine)) = (1 << pinNumber);
else
REG32(baseAdd + GPIO_IRQSTATUS_CLR(intLine)) = (1 << pinNumber);
return 0;
}
// name format: P0.0, range: GPIO0_[31:0] ... GPIO5_[31:0]
static rt_base_t am33xx_pin_get(const char *name)
{
rt_base_t gpiox;
rt_base_t pinNumber;
if (!isdigit((int)name[1]))
return -RT_EINVAL;
gpiox = name[1] - '0';
if (name[2] != '.')
return -RT_EINVAL;
if (!isdigit((int)name[3]))
return -RT_EINVAL;
pinNumber = name[3] - '0';
if (name[4] == '\0')
goto done;
else if (!isdigit((int)name[4]))
return -RT_EINVAL;
pinNumber *= 10;
pinNumber += name[4] - '0';
if (name[5] != '\0')
return -RT_EINVAL;
done:
if (pinNumber > 0x1F)
return -RT_EINVAL;
return GET_PIN(gpiox, pinNumber);
}
static const struct rt_pin_ops am33xx_pin_ops =
{
am33xx_pin_mode,
am33xx_pin_write,
am33xx_pin_read,
am33xx_pin_attach_irq,
am33xx_pin_detach_irq,
am33xx_pin_irq_enable,
am33xx_pin_get,
};
int rt_hw_gpio_init(void)
{
int vector;
rt_base_t gpiox;
char name[RT_NAME_MAX];
for (gpiox = 0; gpiox < 4; gpiox++)
{
rt_snprintf(name, sizeof(name), "%s%d", "gpio", gpiox);
vector = GPIO_INTx[gpiox];
rt_hw_interrupt_install(vector, GPIO_ISRx[gpiox], &GPIO_PARAMx[gpiox], name);
rt_hw_interrupt_control(vector, 0, 0);
rt_hw_interrupt_umask(vector);
}
rt_device_pin_register("gpio", &am33xx_pin_ops, RT_NULL);
return 0;
}
INIT_BOARD_EXPORT(rt_hw_gpio_init);
#endif