RIOT/boards/arduino-zero/include/periph_conf.h

/*
 * Copyright (C)  2016 Freie Universität Berlin
 *                2016 Inria
 *
 * This file is subject to the terms and conditions of the GNU Lesser
 * General Public License v2.1. See the file LICENSE in the top level
 * directory for more details.
 */

/**
 * @ingroup     boards_arduino-zero
 * @{
 *
 * @file
 * @brief       Configuration of CPU peripherals for Arduino Zero board
 *
 * @author      Thomas Eichinger <thomas.eichinger@fu-berlin.de>
 * @author      Hauke Petersen <hauke.petersen@fu-berlin.de>
 * @author      Peter Kietzmann <peter.kietzmann@haw-hamburg.de>
 * @author      Alexandre Abadie <alexandre.abadie@inria.fr>
 */

#ifndef PERIPH_CONF_H_
#define PERIPH_CONF_H_

#include <stdint.h>

#include "cpu.h"
#include "periph_cpu.h"

#ifdef __cplusplus
extern "C" {
#endif

/**
 * @brief   External oscillator and clock configuration
 *
 * For selection of the used CORECLOCK, we have implemented two choices:
 *
 * - usage of the PLL fed by the internal 8MHz oscillator divided by 8
 * - usage of the internal 8MHz oscillator directly, divided by N if needed
 *
 *
 * The PLL option allows for the usage of a wider frequency range and a more
 * stable clock with less jitter. This is why we use this option as default.
 *
 * The target frequency is computed from the PLL multiplier and the PLL divisor.
 * Use the following formula to compute your values:
 *
 * CORECLOCK = ((PLL_MUL + 1) * 1MHz) / PLL_DIV
 *
 * NOTE: The PLL circuit does not run with less than 32MHz while the maximum PLL
 *       frequency is 96MHz. So PLL_MULL must be between 31 and 95!
 *
 *
 * The internal Oscillator used directly can lead to a slightly better power
 * efficiency to the cost of a less stable clock. Use this option when you know
 * what you are doing! The actual core frequency is adjusted as follows:
 *
 * CORECLOCK = 8MHz / DIV
 *
 * NOTE: A core clock frequency below 1MHz is not recommended
 *
 * @{
 */
#define CLOCK_USE_PLL       (1)

#if CLOCK_USE_PLL
/* edit these values to adjust the PLL output frequency */
#define CLOCK_PLL_MUL       (47U)               /* must be >= 31 & <= 95 */
#define CLOCK_PLL_DIV       (1U)                /* adjust to your needs */
/* generate the actual used core clock frequency */
#define CLOCK_CORECLOCK     (((CLOCK_PLL_MUL + 1) * 1000000U) / CLOCK_PLL_DIV)
#else
/* edit this value to your needs */
#define CLOCK_DIV           (1U)
/* generate the actual core clock frequency */
#define CLOCK_CORECLOCK     (8000000 / CLOCK_DIV)
#endif
/** @} */

/**
 * @name Timer peripheral configuration
 * @{
 */
#define TIMER_NUMOF         (2U)
#define TIMER_0_EN          1
#define TIMER_1_EN          1

/* Timer 0 configuration */
#define TIMER_0_DEV         TC3->COUNT16
#define TIMER_0_CHANNELS    2
#define TIMER_0_MAX_VALUE   (0xffff)
#define TIMER_0_ISR         isr_tc3

/* Timer 1 configuration */
#define TIMER_1_DEV         TC4->COUNT32
#define TIMER_1_CHANNELS    2
#define TIMER_1_MAX_VALUE   (0xffffffff)
#define TIMER_1_ISR         isr_tc4

/** @} */

/**
 * @name UART configuration
 * @{
 */
static const uart_conf_t uart_config[] = {
    /* device, RX pin, TX pin, mux, RX pad, TX pad */
    {&SERCOM5->USART, GPIO_PIN(PB,23), GPIO_PIN(PB,22), GPIO_MUX_D, SERCOM_RX_PAD_3, UART_TX_PAD_2},
    {&SERCOM0->USART, GPIO_PIN(PA,11), GPIO_PIN(PA,10), GPIO_MUX_C, SERCOM_RX_PAD_3, UART_TX_PAD_2},
};

/* interrupt function name mapping */
#define UART_0_ISR          isr_sercom5
#define UART_1_ISR          isr_sercom0

#define UART_NUMOF          (sizeof(uart_config) / sizeof(uart_config[0]))
/** @} */

/**
 * @name PWM configuration
 * @{
 */
#define PWM_0_EN            1
#define PWM_1_EN            1
#define PWM_MAX_CHANNELS    2
/* for compatibility with test application */
#define PWM_0_CHANNELS      PWM_MAX_CHANNELS
#define PWM_1_CHANNELS      PWM_MAX_CHANNELS

/* PWM device configuration */
static const pwm_conf_t pwm_config[] = {
#if PWM_0_EN
    {TCC0, {
        /* GPIO pin, MUX value, TCC channel */
        { GPIO_PIN(PA, 8), GPIO_MUX_E,  0 },
        { GPIO_PIN(PA, 9), GPIO_MUX_E,  1 },
    }},
#endif
#if PWM_1_EN
    {TCC1, {
        /* GPIO pin, MUX value, TCC channel */
        { GPIO_PIN(PA, 6), GPIO_MUX_E, 0 },
        { GPIO_PIN(PA, 7), GPIO_MUX_E, 1 },
    }},
#endif
};

/* number of devices that are actually defined */
#define PWM_NUMOF           (2U)
/** @} */

/**
 * @name ADC configuration
 * @{
 */
#define ADC_CONFIG {            \
    { GPIO_PIN(PA, 2), 0, 0  }, \
    { GPIO_PIN(PB, 8), 0, 2  }, \
    { GPIO_PIN(PB, 9), 0, 3  }, \
    { GPIO_PIN(PA, 4), 0, 4  }, \
    { GPIO_PIN(PA, 5), 0, 5  }, \
    { GPIO_PIN(PB, 2), 0, 10 }}

#define ADC_NUMOF           (6)
/** @} */

/**
 * @name SPI configuration
 * @{
 */
#define SPI_NUMOF          (1)
#define SPI_0_EN           1

/*      SPI0             */
#define SPI_0_DEV          SERCOM4->SPI
#define SPI_IRQ_0          SERCOM4_IRQn
#define SPI_0_GCLK_ID      SERCOM4_GCLK_ID_CORE
/* SPI 0 pin configuration */
#define SPI_0_SCLK         GPIO_PIN(PB, 11)
#define SPI_0_SCLK_MUX     GPIO_MUX_D
#define SPI_0_MISO         GPIO_PIN(PA, 12)
#define SPI_0_MISO_MUX     GPIO_MUX_D
#define SPI_0_MISO_PAD     SERCOM_RX_PAD_0
#define SPI_0_MOSI         GPIO_PIN(PB, 10)
#define SPI_0_MOSI_MUX     GPIO_MUX_D
#define SPI_0_MOSI_PAD     SPI_PAD_2_SCK_3

/** @} */

/**
 * @name I2C configuration
 * @{
 */
#define I2C_NUMOF          (1U)
#define I2C_0_EN            1
#define I2C_1_EN            0
#define I2C_2_EN            0
#define I2C_3_EN            0
#define I2C_IRQ_PRIO        1

#define I2C_0_DEV           SERCOM3->I2CM
#define I2C_0_IRQ           SERCOM3_IRQn
#define I2C_0_ISR           isr_sercom3
/* I2C 0 GCLK */
#define I2C_0_GCLK_ID       SERCOM3_GCLK_ID_CORE
#define I2C_0_GCLK_ID_SLOW  SERCOM3_GCLK_ID_SLOW
/* I2C 0 pin configuration */
#define I2C_0_SDA           GPIO_PIN(PA, 22)
#define I2C_0_SCL           GPIO_PIN(PA, 23)
#define I2C_0_MUX           GPIO_MUX_C

/**
 * @name RTC configuration
 * @{
 */
#define RTC_NUMOF           (1U)
#define RTC_DEV             RTC->MODE2
/** @} */

/**
 * @name RTT configuration
 * @{
 */
#define RTT_NUMOF           (1U)
#define RTT_DEV             RTC->MODE0
#define RTT_IRQ             RTC_IRQn
#define RTT_IRQ_PRIO        10
#define RTT_ISR             isr_rtc
#define RTT_MAX_VALUE       (0xffffffff)
#define RTT_FREQUENCY       (32768U)    /* in Hz. For changes see `rtt.c` */
#define RTT_RUNSTDBY        (1)         /* Keep RTT running in sleep states */
/** @} */

#ifdef __cplusplus
}
#endif

#endif /* PERIPH_CONF_H_ */
/** @} */
boards/arduino-zero: add initial support 2016-05-29 15:39:38 +02:00			`/*`
			`* Copyright (C) 2016 Freie Universität Berlin`
			`* 2016 Inria`
			`*`
			`* This file is subject to the terms and conditions of the GNU Lesser`
			`* General Public License v2.1. See the file LICENSE in the top level`
			`* directory for more details.`
			`*/`

			`/**`
			`* @ingroup boards_arduino-zero`
			`* @{`
			`*`
			`* @file`
			`* @brief Configuration of CPU peripherals for Arduino Zero board`
			`*`
			`* @author Thomas Eichinger <thomas.eichinger@fu-berlin.de>`
			`* @author Hauke Petersen <hauke.petersen@fu-berlin.de>`
			`* @author Peter Kietzmann <peter.kietzmann@haw-hamburg.de>`
			`* @author Alexandre Abadie <alexandre.abadie@inria.fr>`
			`*/`

			`#ifndef PERIPH_CONF_H_`
			`#define PERIPH_CONF_H_`

			`#include <stdint.h>`

			`#include "cpu.h"`
			`#include "periph_cpu.h"`

			`#ifdef __cplusplus`
			`extern "C" {`
			`#endif`

			`/**`
			`* @brief External oscillator and clock configuration`
			`*`
			`* For selection of the used CORECLOCK, we have implemented two choices:`
			`*`
			`* - usage of the PLL fed by the internal 8MHz oscillator divided by 8`
			`* - usage of the internal 8MHz oscillator directly, divided by N if needed`
			`*`
			`*`
			`* The PLL option allows for the usage of a wider frequency range and a more`
			`* stable clock with less jitter. This is why we use this option as default.`
			`*`
			`* The target frequency is computed from the PLL multiplier and the PLL divisor.`
			`* Use the following formula to compute your values:`
			`*`
			`* CORECLOCK = ((PLL_MUL + 1) * 1MHz) / PLL_DIV`
			`*`
			`* NOTE: The PLL circuit does not run with less than 32MHz while the maximum PLL`
			`* frequency is 96MHz. So PLL_MULL must be between 31 and 95!`
			`*`
			`*`
			`* The internal Oscillator used directly can lead to a slightly better power`
			`* efficiency to the cost of a less stable clock. Use this option when you know`
			`* what you are doing! The actual core frequency is adjusted as follows:`
			`*`
			`* CORECLOCK = 8MHz / DIV`
			`*`
			`* NOTE: A core clock frequency below 1MHz is not recommended`
			`*`
			`* @{`
			`*/`
			`#define CLOCK_USE_PLL (1)`

			`#if CLOCK_USE_PLL`
			`/* edit these values to adjust the PLL output frequency */`
			`#define CLOCK_PLL_MUL (47U) /* must be >= 31 & <= 95 */`
			`#define CLOCK_PLL_DIV (1U) /* adjust to your needs */`
			`/* generate the actual used core clock frequency */`
			`#define CLOCK_CORECLOCK (((CLOCK_PLL_MUL + 1) * 1000000U) / CLOCK_PLL_DIV)`
			`#else`
			`/* edit this value to your needs */`
			`#define CLOCK_DIV (1U)`
			`/* generate the actual core clock frequency */`
			`#define CLOCK_CORECLOCK (8000000 / CLOCK_DIV)`
			`#endif`
			`/** @} */`

			`/**`
			`* @name Timer peripheral configuration`
			`* @{`
			`*/`
			`#define TIMER_NUMOF (2U)`
			`#define TIMER_0_EN 1`
			`#define TIMER_1_EN 1`

			`/* Timer 0 configuration */`
			`#define TIMER_0_DEV TC3->COUNT16`
			`#define TIMER_0_CHANNELS 2`
			`#define TIMER_0_MAX_VALUE (0xffff)`
			`#define TIMER_0_ISR isr_tc3`

			`/* Timer 1 configuration */`
			`#define TIMER_1_DEV TC4->COUNT32`
			`#define TIMER_1_CHANNELS 2`
			`#define TIMER_1_MAX_VALUE (0xffffffff)`
			`#define TIMER_1_ISR isr_tc4`

			`/** @} */`

			`/**`
			`* @name UART configuration`
			`* @{`
			`*/`
			`static const uart_conf_t uart_config[] = {`
			`/* device, RX pin, TX pin, mux, RX pad, TX pad */`
			`{&SERCOM5->USART, GPIO_PIN(PB,23), GPIO_PIN(PB,22), GPIO_MUX_D, SERCOM_RX_PAD_3, UART_TX_PAD_2},`
			`{&SERCOM0->USART, GPIO_PIN(PA,11), GPIO_PIN(PA,10), GPIO_MUX_C, SERCOM_RX_PAD_3, UART_TX_PAD_2},`
			`};`

			`/* interrupt function name mapping */`
			`#define UART_0_ISR isr_sercom5`
			`#define UART_1_ISR isr_sercom0`

			`#define UART_NUMOF (sizeof(uart_config) / sizeof(uart_config[0]))`
			`/** @} */`

			`/**`
			`* @name PWM configuration`
			`* @{`
			`*/`
			`#define PWM_0_EN 1`
			`#define PWM_1_EN 1`
			`#define PWM_MAX_CHANNELS 2`
			`/* for compatibility with test application */`
			`#define PWM_0_CHANNELS PWM_MAX_CHANNELS`
			`#define PWM_1_CHANNELS PWM_MAX_CHANNELS`

			`/* PWM device configuration */`
			`static const pwm_conf_t pwm_config[] = {`
			`#if PWM_0_EN`
			`{TCC0, {`
			`/* GPIO pin, MUX value, TCC channel */`
			`{ GPIO_PIN(PA, 8), GPIO_MUX_E, 0 },`
			`{ GPIO_PIN(PA, 9), GPIO_MUX_E, 1 },`
			`}},`
			`#endif`
			`#if PWM_1_EN`
			`{TCC1, {`
			`/* GPIO pin, MUX value, TCC channel */`
			`{ GPIO_PIN(PA, 6), GPIO_MUX_E, 0 },`
			`{ GPIO_PIN(PA, 7), GPIO_MUX_E, 1 },`
			`}},`
			`#endif`
			`};`

			`/* number of devices that are actually defined */`
			`#define PWM_NUMOF (2U)`
			`/** @} */`

			`/**`
			`* @name ADC configuration`
			`* @{`
			`*/`
			`#define ADC_CONFIG { \`
			`{ GPIO_PIN(PA, 2), 0, 0 }, \`
			`{ GPIO_PIN(PB, 8), 0, 2 }, \`
			`{ GPIO_PIN(PB, 9), 0, 3 }, \`
			`{ GPIO_PIN(PA, 4), 0, 4 }, \`
			`{ GPIO_PIN(PA, 5), 0, 5 }, \`
			`{ GPIO_PIN(PB, 2), 0, 10 }}`

			`#define ADC_NUMOF (6)`
			`/** @} */`

			`/**`
			`* @name SPI configuration`
			`* @{`
			`*/`
			`#define SPI_NUMOF (1)`
			`#define SPI_0_EN 1`

			`/* SPI0 */`
			`#define SPI_0_DEV SERCOM4->SPI`
			`#define SPI_IRQ_0 SERCOM4_IRQn`
			`#define SPI_0_GCLK_ID SERCOM4_GCLK_ID_CORE`
			`/* SPI 0 pin configuration */`
			`#define SPI_0_SCLK GPIO_PIN(PB, 11)`
			`#define SPI_0_SCLK_MUX GPIO_MUX_D`
			`#define SPI_0_MISO GPIO_PIN(PA, 12)`
			`#define SPI_0_MISO_MUX GPIO_MUX_D`
			`#define SPI_0_MISO_PAD SERCOM_RX_PAD_0`
			`#define SPI_0_MOSI GPIO_PIN(PB, 10)`
			`#define SPI_0_MOSI_MUX GPIO_MUX_D`
			`#define SPI_0_MOSI_PAD SPI_PAD_2_SCK_3`

			`/** @} */`

			`/**`
			`* @name I2C configuration`
			`* @{`
			`*/`
			`#define I2C_NUMOF (1U)`
			`#define I2C_0_EN 1`
			`#define I2C_1_EN 0`
			`#define I2C_2_EN 0`
			`#define I2C_3_EN 0`
			`#define I2C_IRQ_PRIO 1`

			`#define I2C_0_DEV SERCOM3->I2CM`
			`#define I2C_0_IRQ SERCOM3_IRQn`
			`#define I2C_0_ISR isr_sercom3`
			`/* I2C 0 GCLK */`
			`#define I2C_0_GCLK_ID SERCOM3_GCLK_ID_CORE`
			`#define I2C_0_GCLK_ID_SLOW SERCOM3_GCLK_ID_SLOW`
			`/* I2C 0 pin configuration */`
			`#define I2C_0_SDA GPIO_PIN(PA, 22)`
			`#define I2C_0_SCL GPIO_PIN(PA, 23)`
			`#define I2C_0_MUX GPIO_MUX_C`

			`/**`
			`* @name RTC configuration`
			`* @{`
			`*/`
			`#define RTC_NUMOF (1U)`
			`#define RTC_DEV RTC->MODE2`
			`/** @} */`

			`/**`
			`* @name RTT configuration`
			`* @{`
			`*/`
			`#define RTT_NUMOF (1U)`
			`#define RTT_DEV RTC->MODE0`
			`#define RTT_IRQ RTC_IRQn`
			`#define RTT_IRQ_PRIO 10`
			`#define RTT_ISR isr_rtc`
			`#define RTT_MAX_VALUE (0xffffffff)`
			#define RTT_FREQUENCY (32768U) /* in Hz. For changes see `rtt.c` */
			`#define RTT_RUNSTDBY (1) /* Keep RTT running in sleep states */`
			`/** @} */`

			`#ifdef __cplusplus`
			`}`
			`#endif`

			`#endif /* PERIPH_CONF_H_ */`
			`/** @} */`