rtt-f030/bsp/avr32uc3b0/SOFTWARE_FRAMEWORK/DRIVERS/GPIO/gpio.c

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief GPIO driver for AVR32 UC3.
*
* This file defines a useful set of functions for the GPIO.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with a GPIO module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include "gpio.h"
//! GPIO module instance.
#define GPIO AVR32_GPIO
/*! \name Peripheral Bus Interface
*/
//! @{
int gpio_enable_module(const gpio_map_t gpiomap, unsigned int size)
{
int status = GPIO_SUCCESS;
unsigned int i;
for (i = 0; i < size; i++)
{
status |= gpio_enable_module_pin(gpiomap->pin, gpiomap->function);
gpiomap++;
}
return status;
}
int gpio_enable_module_pin(unsigned int pin, unsigned int function)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
// Enable the correct function.
switch (function)
{
case 0: // A function.
gpio_port->pmr0c = 1 << (pin & 0x1F);
gpio_port->pmr1c = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pmr2c = 1 << (pin & 0x1F);
#endif
break;
case 1: // B function.
gpio_port->pmr0s = 1 << (pin & 0x1F);
gpio_port->pmr1c = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pmr2c = 1 << (pin & 0x1F);
#endif
break;
case 2: // C function.
gpio_port->pmr0c = 1 << (pin & 0x1F);
gpio_port->pmr1s = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pmr2c = 1 << (pin & 0x1F);
#endif
break;
case 3: // D function.
gpio_port->pmr0s = 1 << (pin & 0x1F);
gpio_port->pmr1s = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pmr2c = 1 << (pin & 0x1F);
#endif
break;
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
case 4: // E function.
gpio_port->pmr0c = 1 << (pin & 0x1F);
gpio_port->pmr1c = 1 << (pin & 0x1F);
gpio_port->pmr2s = 1 << (pin & 0x1F);
break;
case 5: // F function.
gpio_port->pmr0s = 1 << (pin & 0x1F);
gpio_port->pmr1c = 1 << (pin & 0x1F);
gpio_port->pmr2s = 1 << (pin & 0x1F);
break;
case 6: // G function.
gpio_port->pmr0c = 1 << (pin & 0x1F);
gpio_port->pmr1s = 1 << (pin & 0x1F);
gpio_port->pmr2s = 1 << (pin & 0x1F);
break;
case 7: // H function.
gpio_port->pmr0s = 1 << (pin & 0x1F);
gpio_port->pmr1s = 1 << (pin & 0x1F);
gpio_port->pmr2s = 1 << (pin & 0x1F);
break;
#endif
default:
return GPIO_INVALID_ARGUMENT;
}
// Disable GPIO control.
gpio_port->gperc = 1 << (pin & 0x1F);
return GPIO_SUCCESS;
}
void gpio_enable_gpio(const gpio_map_t gpiomap, unsigned int size)
{
unsigned int i;
for (i = 0; i < size; i++)
{
gpio_enable_gpio_pin(gpiomap->pin);
gpiomap++;
}
}
void gpio_enable_gpio_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->oderc = 1 << (pin & 0x1F);
gpio_port->gpers = 1 << (pin & 0x1F);
}
// The open-drain mode is not synthesized on the current AVR32 products.
// If one day some AVR32 products have this feature, the corresponding part
// numbers should be listed in the #if below.
// Note that other functions are available in this driver to use pins with open
// drain in GPIO mode. The advantage of the open-drain mode functions over these
// other functions is that they can be used not only in GPIO mode but also in
// module mode.
#if 0
void gpio_enable_pin_open_drain(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->odmers = 1 << (pin & 0x1F);
}
void gpio_disable_pin_open_drain(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->odmerc = 1 << (pin & 0x1F);
}
#endif
void gpio_enable_pin_pull_up(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puers = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_200_H_INCLUDED) || defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pderc = 1 << (pin & 0x1F);
#endif
}
void gpio_disable_pin_pull_up(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puerc = 1 << (pin & 0x1F);
}
#if defined(AVR32_GPIO_200_H_INCLUDED) || defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
// Added support of Pull-up Resistor, Pull-down Resistor and Buskeeper Control.
/*! \brief Enables the pull-down resistor of a pin.
*
* \param pin The pin number.
*/
void gpio_enable_pin_pull_down(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puerc = 1 << (pin & 0x1F);
gpio_port->pders = 1 << (pin & 0x1F);
}
/*! \brief Disables the pull-down resistor of a pin.
*
* \param pin The pin number.
*/
void gpio_disable_pin_pull_down(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->pderc = 1 << (pin & 0x1F);
}
/*! \brief Enables the buskeeper functionality on a pin.
*
* \param pin The pin number.
*/
void gpio_enable_pin_buskeeper(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puers = 1 << (pin & 0x1F);
gpio_port->pders = 1 << (pin & 0x1F);
}
/*! \brief Disables the buskeeper functionality on a pin.
*
* \param pin The pin number.
*/
void gpio_disable_pin_buskeeper(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puerc = 1 << (pin & 0x1F);
gpio_port->pderc = 1 << (pin & 0x1F);
}
#endif
int gpio_get_pin_value(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
return (gpio_port->pvr >> (pin & 0x1F)) & 1;
}
int gpio_get_gpio_pin_output_value(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
return (gpio_port->ovr >> (pin & 0x1F)) & 1;
}
int gpio_get_gpio_open_drain_pin_output_value(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
return ((gpio_port->oder >> (pin & 0x1F)) & 1) ^ 1;
}
void gpio_set_gpio_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrs = 1 << (pin & 0x1F); // Value to be driven on the I/O line: 1.
gpio_port->oders = 1 << (pin & 0x1F); // The GPIO output driver is enabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_clr_gpio_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrc = 1 << (pin & 0x1F); // Value to be driven on the I/O line: 0.
gpio_port->oders = 1 << (pin & 0x1F); // The GPIO output driver is enabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_tgl_gpio_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrt = 1 << (pin & 0x1F); // Toggle the I/O line.
gpio_port->oders = 1 << (pin & 0x1F); // The GPIO output driver is enabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_set_gpio_open_drain_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->oderc = 1 << (pin & 0x1F); // The GPIO output driver is disabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_clr_gpio_open_drain_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrc = 1 << (pin & 0x1F); // Value to be driven on the I/O line: 0.
gpio_port->oders = 1 << (pin & 0x1F); // The GPIO output driver is enabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_tgl_gpio_open_drain_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrc = 1 << (pin & 0x1F); // Value to be driven on the I/O line if the GPIO output driver is enabled: 0.
gpio_port->odert = 1 << (pin & 0x1F); // The GPIO output driver is toggled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_enable_pin_glitch_filter(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->gfers = 1 << (pin & 0x1F);
}
void gpio_disable_pin_glitch_filter(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->gferc = 1 << (pin & 0x1F);
}
/*! \brief Configure the edge detector of an input pin
*
* \param pin The pin number.
* \param mode The edge detection mode (\ref GPIO_PIN_CHANGE, \ref GPIO_RISING_EDGE
* or \ref GPIO_FALLING_EDGE).
*
* \return \ref GPIO_SUCCESS or \ref GPIO_INVALID_ARGUMENT.
*/
static int gpio_configure_edge_detector(unsigned int pin, unsigned int mode)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
// Configure the edge detector.
switch (mode)
{
case GPIO_PIN_CHANGE:
gpio_port->imr0c = 1 << (pin & 0x1F);
gpio_port->imr1c = 1 << (pin & 0x1F);
break;
case GPIO_RISING_EDGE:
gpio_port->imr0s = 1 << (pin & 0x1F);
gpio_port->imr1c = 1 << (pin & 0x1F);
break;
case GPIO_FALLING_EDGE:
gpio_port->imr0c = 1 << (pin & 0x1F);
gpio_port->imr1s = 1 << (pin & 0x1F);
break;
default:
return GPIO_INVALID_ARGUMENT;
}
return GPIO_SUCCESS;
}
int gpio_enable_pin_interrupt(unsigned int pin, unsigned int mode)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
// Enable the glitch filter.
gpio_port->gfers = 1 << (pin & 0x1F);
// Configure the edge detector.
if(GPIO_INVALID_ARGUMENT == gpio_configure_edge_detector(pin, mode))
return(GPIO_INVALID_ARGUMENT);
// Enable interrupt.
gpio_port->iers = 1 << (pin & 0x1F);
return GPIO_SUCCESS;
}
void gpio_disable_pin_interrupt(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ierc = 1 << (pin & 0x1F);
}
int gpio_get_pin_interrupt_flag(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
return (gpio_port->ifr >> (pin & 0x1F)) & 1;
}
void gpio_clear_pin_interrupt_flag(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ifrc = 1 << (pin & 0x1F);
}
//#
//# Peripheral Event System Support.
//#
#if UC3L
int gpio_configure_pin_periph_event_mode(unsigned int pin, unsigned int mode, unsigned int use_igf)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
if(TRUE == use_igf)
{
// Enable the glitch filter.
gpio_port->gfers = 1 << (pin & 0x1F);
}
else
{
// Disable the glitch filter.
gpio_port->gferc = 1 << (pin & 0x1F);
}
// Configure the edge detector.
return(gpio_configure_edge_detector(pin, mode));
}
#endif
//! @}