incubator-nuttx/boards/arm/kinetis/freedom-k64f/include/board.h

/****************************************************************************
 * boards/arm/kinetis/freedom-k64f/include/board.h
 *
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.  The
 * ASF licenses this file to you under the Apache License, Version 2.0 (the
 * "License"); you may not use this file except in compliance with the
 * License.  You may obtain a copy of the License at
 *
 *   http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
 * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.  See the
 * License for the specific language governing permissions and limitations
 * under the License.
 *
 ****************************************************************************/

#ifndef __BOARDS_ARM_KINETIS_FREEDOM_K64F_INCLUDE_BOARD_H
#define __BOARDS_ARM_KINETIS_FREEDOM_K64F_INCLUDE_BOARD_H

/****************************************************************************
 * Included Files
 ****************************************************************************/

#include <nuttx/config.h>

#ifndef __ASSEMBLY__
#  include <stdint.h>
#endif

/****************************************************************************
 * Pre-processor Definitions
 ****************************************************************************/

/* Clocking *****************************************************************/

/* The Freedom K64F uses a 50MHz external clock from the Micrel Ethernet PHY.
 * The Kinetis MCU startup from an internal digitally-controlled oscillator
 * (DCO). NuttX will enable the main external oscillator (EXTAL0/XTAL0).
 * The external oscillator/resonator can range from 32.768 KHz up to 50 MHz.
 * The default external source for the MCG oscillator inputs (EXTAL) is
 * 50 MHz clock source from Micrel Ethernet PHY.
 */

#define BOARD_EXTCLOCK       1          /* External clock */
#define BOARD_EXTAL_FREQ     50000000   /* 50MHz Oscillator from Micrel PHY */
#define BOARD_XTAL32_FREQ    32768      /* 32KHz RTC Oscillator */

/* PLL Configuration.  Either the external clock or crystal frequency is used
 * to select the PRDIV value.
 * Only reference clock frequencies are supported that will produce
 * a KINETIS_MCG_PLL_REF_MIN >= PLLIN <= KINETIS_MCG_PLL_REF_MIN reference
 * clock to the PLL.
 *
 *   PLL Input frequency:   PLLIN  = REFCLK / PRDIV = 50  MHz  / 20 = 2.5 MHz
 *   PLL Output frequency:  PLLOUT = PLLIN  * VDIV  = 2.5 MHz  * 48 = 120 MHz
 *   MCG Frequency:         PLLOUT = 120 MHz
 *
 * PRDIV register value is the divider minus KINETIS_MCG_C5_PRDIV_BASE.
 * VDIV  register value is offset by KINETIS_MCG_C6_VDIV_BASE.
 */

#define BOARD_PRDIV          20   /* PLL External Reference Divider */
#define BOARD_VDIV           48   /* PLL VCO Divider (frequency multiplier) */

#define BOARD_PLLIN_FREQ     (BOARD_EXTAL_FREQ / BOARD_PRDIV)
#define BOARD_PLLOUT_FREQ    (BOARD_PLLIN_FREQ * BOARD_VDIV)
#define BOARD_MCG_FREQ       BOARD_PLLOUT_FREQ

/* Define additional MCG_C2 Setting */

#define BOARD_MCG_C2_FCFTRIM 0              /* Do not enable FCFTRIM */
#define BOARD_MCG_C2_LOCRE0  MCG_C2_LOCRE0  /* Enable reset on loss of clock */

/* SIM CLKDIV1 dividers */

#define BOARD_OUTDIV1        1              /* Core        = MCG,    120 MHz */
#define BOARD_OUTDIV2        2              /* Bus         = MCG / 2, 60 MHz */
#define BOARD_OUTDIV3        2              /* FlexBus     = MCG / 2, 60 MHz */
#define BOARD_OUTDIV4        5              /* Flash clock = MCG / 5, 24 MHz */

#define BOARD_CORECLK_FREQ  (BOARD_MCG_FREQ / BOARD_OUTDIV1)
#define BOARD_BUS_FREQ      (BOARD_MCG_FREQ / BOARD_OUTDIV2)
#define BOARD_FLEXBUS_FREQ  (BOARD_MCG_FREQ / BOARD_OUTDIV3)
#define BOARD_FLASHCLK_FREQ (BOARD_MCG_FREQ / BOARD_OUTDIV4)

/* Use BOARD_MCG_FREQ as the output SIM_SOPT2 MUX selected by
 * SIM_SOPT2[PLLFLLSEL]
 */

#define BOARD_SOPT2_PLLFLLSEL   SIM_SOPT2_PLLFLLSEL_MCGPLLCLK
#define BOARD_SOPT2_FREQ        BOARD_MCG_FREQ

/* Divider output clock = Divider input clock * ((USBFRAC+1) / (USBDIV+1))
 *     SIM_CLKDIV2_FREQ = BOARD_SOPT2_FREQ * ((USBFRAC+1) / (USBDIV+1))
 *     SIM_CLKDIV2_FREQ = BOARD_SOPT2_FREQ / (USBDIV+1)* (USBFRAC+1)
 *                48MHz = 120MHz / (4 + 1) * (1 + 1)
 */

#if (BOARD_SOPT2_FREQ == 120000000L)
#  define BOARD_SIM_CLKDIV2_USBFRAC     2
#  define BOARD_SIM_CLKDIV2_USBDIV      5
#  define BOARD_SIM_CLKDIV2_FREQ        (BOARD_SOPT2_FREQ / \
                                         BOARD_SIM_CLKDIV2_USBDIV * \
                                         BOARD_SIM_CLKDIV2_USBFRAC)
#endif

/* SDHC clocking ************************************************************/

/* SDCLK configurations corresponding to various modes of operation.
 * Formula is:
 *
 *   SDCLK  frequency = (base clock) / (prescaler * divisor)
 *
 * The SDHC module is always configure configured so that the core clock is
 * the base clock.
 * Possible values for presscaler and divisor are:
 *
 *   SDCLKFS: {2, 4, 8, 16, 32, 63, 128, 256}
 *   DVS:     {1..16}
 */

/* Identification mode:
 * Optimal 400KHz, Actual 120MHz / (32 * 10) = 375 Khz
 */

#define BOARD_SDHC_IDMODE_PRESCALER    SDHC_SYSCTL_SDCLKFS_DIV32
#define BOARD_SDHC_IDMODE_DIVISOR      SDHC_SYSCTL_DVS_DIV(10)

/* MMC normal mode:
 * Optimal 20MHz, Actual 120MHz / (2 * 3) = 20 MHz
 */

#define BOARD_SDHC_MMCMODE_PRESCALER   SDHC_SYSCTL_SDCLKFS_DIV2
#define BOARD_SDHC_MMCMODE_DIVISOR     SDHC_SYSCTL_DVS_DIV(3)

/* SD normal mode (1-bit):
 * Optimal 20MHz, Actual 120MHz / (2 * 3) = 20 MHz
 */

#define BOARD_SDHC_SD1MODE_PRESCALER   SDHC_SYSCTL_SDCLKFS_DIV2
#define BOARD_SDHC_SD1MODE_DIVISOR     SDHC_SYSCTL_DVS_DIV(3)

/* SD normal mode (4-bit):
 * Optimal 25MHz, Actual 120MHz / (2 * 3) = 20 MHz (with DMA)
 * SD normal mode (4-bit):
 * Optimal 20MHz, Actual 120MHz / (2 * 3) = 20 MHz (no DMA)
 */

#ifdef CONFIG_SDIO_DMA
#  define BOARD_SDHC_SD4MODE_PRESCALER SDHC_SYSCTL_SDCLKFS_DIV2
#  define BOARD_SDHC_SD4MODE_DIVISOR   SDHC_SYSCTL_DVS_DIV(3)
#else
#  define BOARD_SDHC_SD4MODE_PRESCALER SDHC_SYSCTL_SDCLKFS_DIV2
#  define BOARD_SDHC_SD4MODE_DIVISOR   SDHC_SYSCTL_DVS_DIV(3)
#endif

/* Use the output of SIM_SOPT2[PLLFLLSEL] as the USB clock source */

#define BOARD_USB_CLKSRC               SIM_SOPT2_USBSRC
#define BOARD_USB_FREQ                 BOARD_SIM_CLKDIV2_FREQ

/* Allow USBOTG-FS Controller to Read from FLASH */

#define BOARD_USB_FLASHACCESS

/* PWM Configuration */

/* FTM0 Channels */

/* Channels can be modified using kinetis_k64pinmux.h */

#define GPIO_FTM0_CH0OUT PIN_FTM0_CH0_1
#define GPIO_FTM0_CH1OUT PIN_FTM0_CH1_1
#define GPIO_FTM0_CH2OUT PIN_FTM0_CH2_2
#define GPIO_FTM0_CH3OUT PIN_FTM0_CH3_1
#define GPIO_FTM0_CH4OUT PIN_FTM0_CH4_1
#define GPIO_FTM0_CH5OUT PIN_FTM0_CH5_1

/* LED definitions **********************************************************/

/* The Freedom K64F has a single RGB LED driven by the K64F as follows:
 *
 *   LED    K64
 *   ------ -------------------------------------------------------
 *   RED    PTB22/SPI2_SOUT/FB_AD29/CMP2_OUT
 *   BLUE   PTB21/SPI2_SCK/FB_AD30/CMP1_OUT
 *   GREEN  PTE26/ENET_1588_CLKIN/UART4_CTS_b/RTC_CLKOUT/USB0_CLKIN
 *
 * If CONFIG_ARCH_LEDS is not defined, then the user can control the LEDs
 * in any way.
 *  The following definitions are used to access individual LEDs.
 */

/* LED index values for use with board_userled() */

#define BOARD_LED_R       0
#define BOARD_LED_G       1
#define BOARD_LED_B       2
#define BOARD_NLEDS       3

/* LED bits for use with board_userled_all() */

#define BOARD_LED_R_BIT   (1 << BOARD_LED_R)
#define BOARD_LED_G_BIT   (1 << BOARD_LED_G)
#define BOARD_LED_B_BIT   (1 << BOARD_LED_B)

/* If CONFIG_ARCH_LEDs is defined, then NuttX will control the LED on board
 * the Freedom K64F.  The following definitions describe how NuttX controls
 * the LEDs:
 *
 *   SYMBOL                Meaning                      LED state
 *                                                      RED   GREEN  BLUE
 *   -------------------  ----------------------------  -----------------
 */
#define LED_STARTED       1 /* NuttX has been started    OFF   OFF    OFF */
#define LED_HEAPALLOCATE  2 /* Heap has been allocated   OFF   OFF    ON  */
#define LED_IRQSENABLED   0 /* Interrupts enabled        OFF   OFF    ON  */
#define LED_STACKCREATED  3 /* Idle stack created        OFF   ON     OFF */
#define LED_INIRQ         0 /* In an interrupt          (no change)       */
#define LED_SIGNAL        0 /* In a signal handler      (no change)       */
#define LED_ASSERTION     0 /* An assertion failed      (no change)       */
#define LED_PANIC         4 /* The system has crashed    FLASH OFF    OFF */
#undef  LED_IDLE            /* K64 is in sleep mode     (Not used)        */

/* Button definitions *******************************************************/

/* Two push buttons, SW2 and SW3, are available on FRDM-K64F board,
 * where SW2 is connected to PTC6 and SW3 is connected to PTA4.
 * Besides the general purpose input/output functions, SW2 and SW3 can be
 * low-power wake up signal. Also, only SW3 can be a non-maskable interrupt.
 *
 *   Switch  GPIO Function
 *   ------- ---------------------------------------------------------------
 *   SW2     PTC6/SPI0_SOUT/PD0_EXTRG/I2S0_RX_BCLK/FB_AD9/I2S0_MCLK/LLWU_P10
 *   SW3     PTA4/FTM0_CH1/NMI_b/LLWU_P3
 */

#define BUTTON_SW2        0
#define BUTTON_SW3        1
#define NUM_BUTTONS       2

#define BUTTON_SW2_BIT    (1 << BUTTON_SW2)
#define BUTTON_SW3_BIT    (1 << BUTTON_SW3)

/* Alternative pin resolution ***********************************************/

/* If there are alternative configurations for various pins in the
 * kinetis_k64pinmux.h header file, those alternative pins will be labeled
 * with a suffix like _1, _2, etc.  The logic in this file must select the
 * correct pin configuration for the board by defining a pin configuration
 * (with no suffix) that maps to the correct alternative.
 */

/* The primary serial port interface signals are PTB16 UART0_RX and
 * PTB17 UART0_TX.
 * These signals are connected to the OpenSDAv2 circuit.
 */

#define PIN_UART0_RX      PIN_UART0_RX_3
#define PIN_UART0_TX      PIN_UART0_TX_3

/* An alternative serial port might use a standard serial shield mounted
 * on the Freedom Board.  In this case, Arduino pin D1 provides UART TX and
 * pin D0 provides UART RX.
 *
 * The I/O headers on the FRDM-K64F board are arranged to enable
 * compatibility with Arduino shield. The outer rows of pins (even numbered
 * pins) on the headers, share the same mechanical spacing and placement with
 * the I/O headers on the Arduino Revision 3 (R3) standard.
 *
 * The Arduino D0 and D1 pins then correspond to pins 2 and 4 on the J1 I/O
 * connector:
 *
 *   Arduino Pin              FRDM-K64F J1 Connector
 *   ------------------------ -----------------------
 *   UART TX, Arduino D1 pin  Pin 4, PTC17, UART3_TX
 *   UART RX, Arduino D0 pin  Pin 2, PTC16, UART3_RX
 */

#define PIN_UART3_RX      PIN_UART3_RX_2
#define PIN_UART3_TX      PIN_UART3_TX_2

/* I2C Bus 0
 *
 *  Pin Name   K64   Name
 *  ---- ----- ------ ---------
 *   11  SCL    PTE24  2C0_SCL
 *   12  SDA    PTE25  2C0_SDA
 */

#define PIN_I2C0_SCL      PIN_I2C0_SCL_4
#define PIN_I2C0_SDA      PIN_I2C0_SDA_4

#endif /* __BOARDS_ARM_FREEDOM_K64F_INCLUDE_BOARD_H */