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C

/* Auto-generated config file hpl_sercom_config.h */
#ifndef HPL_SERCOM_CONFIG_H
#define HPL_SERCOM_CONFIG_H
// <<< Use Configuration Wizard in Context Menu >>>
#include <peripheral_clk_config.h>
#ifndef CONF_SERCOM_0_USART_ENABLE
#define CONF_SERCOM_0_USART_ENABLE 1
#endif
// <h> Basic Configuration
// <q> Receive buffer enable
// <i> Enable input buffer in SERCOM module
// <id> usart_rx_enable
#ifndef CONF_SERCOM_0_USART_RXEN
#define CONF_SERCOM_0_USART_RXEN 1
#endif
// <q> Transmitt buffer enable
// <i> Enable output buffer in SERCOM module
// <id> usart_tx_enable
#ifndef CONF_SERCOM_0_USART_TXEN
#define CONF_SERCOM_0_USART_TXEN 1
#endif
// <o> Frame parity
// <0x0=>No parity
// <0x1=>Even parity
// <0x2=>Odd parity
// <i> Parity bit mode for USART frame
// <id> usart_parity
#ifndef CONF_SERCOM_0_USART_PARITY
#define CONF_SERCOM_0_USART_PARITY 0x0
#endif
// <o> Character Size
// <0x0=>8 bits
// <0x1=>9 bits
// <0x5=>5 bits
// <0x6=>6 bits
// <0x7=>7 bits
// <i> Data character size in USART frame
// <id> usart_character_size
#ifndef CONF_SERCOM_0_USART_CHSIZE
#define CONF_SERCOM_0_USART_CHSIZE 0x0
#endif
// <o> Stop Bit
// <0=>One stop bit
// <1=>Two stop bits
// <i> Number of stop bits in USART frame
// <id> usart_stop_bit
#ifndef CONF_SERCOM_0_USART_SBMODE
#define CONF_SERCOM_0_USART_SBMODE 0
#endif
// <o> Baud rate <1-6250000>
// <i> USART baud rate setting
// <id> usart_baud_rate
#ifndef CONF_SERCOM_0_USART_BAUD
#define CONF_SERCOM_0_USART_BAUD 9600
#endif
// </h>
// <e> Advanced configuration
// <id> usart_advanced
#ifndef CONF_SERCOM_0_USART_ADVANCED_CONFIG
#define CONF_SERCOM_0_USART_ADVANCED_CONFIG 0
#endif
// <q> Run in stand-by
// <i> Keep the module running in standby sleep mode
// <id> usart_arch_runstdby
#ifndef CONF_SERCOM_0_USART_RUNSTDBY
#define CONF_SERCOM_0_USART_RUNSTDBY 0
#endif
// <q> Immediate Buffer Overflow Notification
// <i> Controls when the BUFOVF status bit is asserted
// <id> usart_arch_ibon
#ifndef CONF_SERCOM_0_USART_IBON
#define CONF_SERCOM_0_USART_IBON 0
#endif
// <q> Start of Frame Detection Enable
// <i> Will wake the device from any sleep mode if usart_init and usart_enable was run priort to going to sleep. (receive buffer must be enabled)
// <id> usart_arch_sfde
#ifndef CONF_SERCOM_0_USART_SFDE
#define CONF_SERCOM_0_USART_SFDE 0
#endif
// <q> Collision Detection Enable
// <i> Collision detection enable
// <id> usart_arch_cloden
#ifndef CONF_SERCOM_0_USART_CLODEN
#define CONF_SERCOM_0_USART_CLODEN 0
#endif
// <o> Operating Mode
// <0x0=>USART with external clock
// <0x1=>USART with internal clock
// <i> Drive the shift register by an internal clock generated by the baud rate generator or an external clock supplied on the XCK pin.
// <id> usart_arch_clock_mode
#ifndef CONF_SERCOM_0_USART_MODE
#define CONF_SERCOM_0_USART_MODE 0x1
#endif
// <o> Sample Rate
// <0x0=>16x arithmetic
// <0x1=>16x fractional
// <0x2=>8x arithmetic
// <0x3=>8x fractional
// <0x4=>3x arithmetic
// <i> How many over-sampling bits used when sampling data state
// <id> usart_arch_sampr
#ifndef CONF_SERCOM_0_USART_SAMPR
#define CONF_SERCOM_0_USART_SAMPR 0x0
#endif
// <o> Sample Adjustment
// <0x0=>7-8-9 (3-4-5 8-bit over-sampling)
// <0x1=>9-10-11 (4-5-6 8-bit over-sampling)
// <0x2=>11-12-13 (5-6-7 8-bit over-sampling)
// <0x3=>13-14-15 (6-7-8 8-bit over-sampling)
// <i> Adjust which samples to use for data sampling in asynchronous mode
// <id> usart_arch_sampa
#ifndef CONF_SERCOM_0_USART_SAMPA
#define CONF_SERCOM_0_USART_SAMPA 0x0
#endif
// <o> Fractional Part <0-7>
// <i> Fractional part of the baud rate if baud rate generator is in fractional mode
// <id> usart_arch_fractional
#ifndef CONF_SERCOM_0_USART_FRACTIONAL
#define CONF_SERCOM_0_USART_FRACTIONAL 0x0
#endif
// <o> Data Order
// <0=>MSB is transmitted first
// <1=>LSB is transmitted first
// <i> Data order of the data bits in the frame
// <id> usart_arch_dord
#ifndef CONF_SERCOM_0_USART_DORD
#define CONF_SERCOM_0_USART_DORD 1
#endif
// Does not do anything in UART mode
#define CONF_SERCOM_0_USART_CPOL 0
// <o> Encoding Format
// <0=>No encoding
// <1=>IrDA encoded
// <id> usart_arch_enc
#ifndef CONF_SERCOM_0_USART_ENC
#define CONF_SERCOM_0_USART_ENC 0
#endif
// <o> LIN Slave Enable
// <i> Break Character Detection and Auto-Baud/LIN Slave Enable.
// <i> Additional setting needed: 16x sample rate using fractional baud rate generation (CTRLA.SAMPR = 1).
// <0=>Disable
// <1=>Enable
// <id> usart_arch_lin_slave_enable
#ifndef CONF_SERCOM_0_USART_LIN_SLAVE_ENABLE
#define CONF_SERCOM_0_USART_LIN_SLAVE_ENABLE 0
#endif
// <o> Debug Stop Mode
// <i> Behavior of the baud-rate generator when CPU is halted by external debugger.
// <0=>Keep running
// <1=>Halt
// <id> usart_arch_dbgstop
#ifndef CONF_SERCOM_0_USART_DEBUG_STOP_MODE
#define CONF_SERCOM_0_USART_DEBUG_STOP_MODE 0
#endif
// </e>
#ifndef CONF_SERCOM_0_USART_INACK
#define CONF_SERCOM_0_USART_INACK 0x0
#endif
#ifndef CONF_SERCOM_0_USART_DSNACK
#define CONF_SERCOM_0_USART_DSNACK 0x0
#endif
#ifndef CONF_SERCOM_0_USART_MAXITER
#define CONF_SERCOM_0_USART_MAXITER 0x7
#endif
#ifndef CONF_SERCOM_0_USART_GTIME
#define CONF_SERCOM_0_USART_GTIME 0x2
#endif
#define CONF_SERCOM_0_USART_RXINV 0x0
#define CONF_SERCOM_0_USART_TXINV 0x0
#ifndef CONF_SERCOM_0_USART_CMODE
#define CONF_SERCOM_0_USART_CMODE 0
#endif
#ifndef CONF_SERCOM_0_USART_RXPO
#define CONF_SERCOM_0_USART_RXPO 1 /* RX is on PIN_PA05 */
#endif
#ifndef CONF_SERCOM_0_USART_TXPO
#define CONF_SERCOM_0_USART_TXPO 0 /* TX is on PIN_PA04 */
#endif
/* Set correct parity settings in register interface based on PARITY setting */
#if CONF_SERCOM_0_USART_LIN_SLAVE_ENABLE == 1
#if CONF_SERCOM_0_USART_PARITY == 0
#define CONF_SERCOM_0_USART_PMODE 0
#define CONF_SERCOM_0_USART_FORM 4
#else
#define CONF_SERCOM_0_USART_PMODE CONF_SERCOM_0_USART_PARITY - 1
#define CONF_SERCOM_0_USART_FORM 5
#endif
#else /* #if CONF_SERCOM_0_USART_LIN_SLAVE_ENABLE == 0 */
#if CONF_SERCOM_0_USART_PARITY == 0
#define CONF_SERCOM_0_USART_PMODE 0
#define CONF_SERCOM_0_USART_FORM 0
#else
#define CONF_SERCOM_0_USART_PMODE CONF_SERCOM_0_USART_PARITY - 1
#define CONF_SERCOM_0_USART_FORM 1
#endif
#endif
// Calculate BAUD register value in UART mode
#if CONF_SERCOM_0_USART_SAMPR == 0
#ifndef CONF_SERCOM_0_USART_BAUD_RATE
#define CONF_SERCOM_0_USART_BAUD_RATE \
65536 - ((65536 * 16.0f * CONF_SERCOM_0_USART_BAUD) / CONF_GCLK_SERCOM0_CORE_FREQUENCY)
#endif
#ifndef CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH
#define CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH 0
#endif
#elif CONF_SERCOM_0_USART_SAMPR == 1
#ifndef CONF_SERCOM_0_USART_BAUD_RATE
#define CONF_SERCOM_0_USART_BAUD_RATE \
((CONF_GCLK_SERCOM0_CORE_FREQUENCY) / (CONF_SERCOM_0_USART_BAUD * 16)) - (CONF_SERCOM_0_USART_FRACTIONAL / 8)
#endif
#ifndef CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH
#define CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH 0
#endif
#elif CONF_SERCOM_0_USART_SAMPR == 2
#ifndef CONF_SERCOM_0_USART_BAUD_RATE
#define CONF_SERCOM_0_USART_BAUD_RATE \
65536 - ((65536 * 8.0f * CONF_SERCOM_0_USART_BAUD) / CONF_GCLK_SERCOM0_CORE_FREQUENCY)
#endif
#ifndef CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH
#define CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH 0
#endif
#elif CONF_SERCOM_0_USART_SAMPR == 3
#ifndef CONF_SERCOM_0_USART_BAUD_RATE
#define CONF_SERCOM_0_USART_BAUD_RATE \
((CONF_GCLK_SERCOM0_CORE_FREQUENCY) / (CONF_SERCOM_0_USART_BAUD * 8)) - (CONF_SERCOM_0_USART_FRACTIONAL / 8)
#endif
#ifndef CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH
#define CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH 0
#endif
#elif CONF_SERCOM_0_USART_SAMPR == 4
#ifndef CONF_SERCOM_0_USART_BAUD_RATE
#define CONF_SERCOM_0_USART_BAUD_RATE \
65536 - ((65536 * 3.0f * CONF_SERCOM_0_USART_BAUD) / CONF_GCLK_SERCOM0_CORE_FREQUENCY)
#endif
#ifndef CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH
#define CONF_SERCOM_0_USART_RECEIVE_PULSE_LENGTH 0
#endif
#endif
#include <peripheral_clk_config.h>
// Enable configuration of module
#ifndef CONF_SERCOM_6_SPI_ENABLE
#define CONF_SERCOM_6_SPI_ENABLE 1
#endif
// Set module in SPI Master mode
#ifndef CONF_SERCOM_6_SPI_MODE
#define CONF_SERCOM_6_SPI_MODE 0x03
#endif
// <h> Basic Configuration
// <q> Receive buffer enable
// <i> Enable receive buffer to receive data from slave (RXEN)
// <id> spi_master_rx_enable
#ifndef CONF_SERCOM_6_SPI_RXEN
#define CONF_SERCOM_6_SPI_RXEN 0x1
#endif
// <o> Character Size
// <i> Bit size for all characters sent over the SPI bus (CHSIZE)
// <0x0=>8 bits
// <0x1=>9 bits
// <id> spi_master_character_size
#ifndef CONF_SERCOM_6_SPI_CHSIZE
#define CONF_SERCOM_6_SPI_CHSIZE 0x0
#endif
// <o> Baud rate <1-18000000>
// <i> The SPI data transfer rate
// <id> spi_master_baud_rate
#ifndef CONF_SERCOM_6_SPI_BAUD
#define CONF_SERCOM_6_SPI_BAUD 20000
#endif
// </h>
// <e> Advanced Configuration
// <id> spi_master_advanced
#ifndef CONF_SERCOM_6_SPI_ADVANCED
#define CONF_SERCOM_6_SPI_ADVANCED 0
#endif
// <o> Dummy byte <0x00-0x1ff>
// <id> spi_master_dummybyte
// <i> Dummy byte used when reading data from the slave without sending any data
#ifndef CONF_SERCOM_6_SPI_DUMMYBYTE
#define CONF_SERCOM_6_SPI_DUMMYBYTE 0x1ff
#endif
// <o> Data Order
// <0=>MSB first
// <1=>LSB first
// <i> I least significant or most significant bit is shifted out first (DORD)
// <id> spi_master_arch_dord
#ifndef CONF_SERCOM_6_SPI_DORD
#define CONF_SERCOM_6_SPI_DORD 0x0
#endif
// <o> Clock Polarity
// <0=>SCK is low when idle
// <1=>SCK is high when idle
// <i> Determines if the leading edge is rising or falling with a corresponding opposite edge at the trailing edge. (CPOL)
// <id> spi_master_arch_cpol
#ifndef CONF_SERCOM_6_SPI_CPOL
#define CONF_SERCOM_6_SPI_CPOL 0x0
#endif
// <o> Clock Phase
// <0x0=>Sample input on leading edge
// <0x1=>Sample input on trailing edge
// <i> Determines if input data is sampled on leading or trailing SCK edge. (CPHA)
// <id> spi_master_arch_cpha
#ifndef CONF_SERCOM_6_SPI_CPHA
#define CONF_SERCOM_6_SPI_CPHA 0x0
#endif
// <o> Immediate Buffer Overflow Notification
// <i> Controls when OVF is asserted (IBON)
// <0x0=>In data stream
// <0x1=>On buffer overflow
// <id> spi_master_arch_ibon
#ifndef CONF_SERCOM_6_SPI_IBON
#define CONF_SERCOM_6_SPI_IBON 0x0
#endif
// <q> Run in stand-by
// <i> Module stays active in stand-by sleep mode. (RUNSTDBY)
// <id> spi_master_arch_runstdby
#ifndef CONF_SERCOM_6_SPI_RUNSTDBY
#define CONF_SERCOM_6_SPI_RUNSTDBY 0x0
#endif
// <o> Debug Stop Mode
// <i> Behavior of the baud-rate generator when CPU is halted by external debugger. (DBGSTOP)
// <0=>Keep running
// <1=>Halt
// <id> spi_master_arch_dbgstop
#ifndef CONF_SERCOM_6_SPI_DBGSTOP
#define CONF_SERCOM_6_SPI_DBGSTOP 0
#endif
// </e>
// Address mode disabled in master mode
#ifndef CONF_SERCOM_6_SPI_AMODE_EN
#define CONF_SERCOM_6_SPI_AMODE_EN 0
#endif
#ifndef CONF_SERCOM_6_SPI_AMODE
#define CONF_SERCOM_6_SPI_AMODE 0
#endif
#ifndef CONF_SERCOM_6_SPI_ADDR
#define CONF_SERCOM_6_SPI_ADDR 0
#endif
#ifndef CONF_SERCOM_6_SPI_ADDRMASK
#define CONF_SERCOM_6_SPI_ADDRMASK 0
#endif
#ifndef CONF_SERCOM_6_SPI_SSDE
#define CONF_SERCOM_6_SPI_SSDE 0
#endif
#ifndef CONF_SERCOM_6_SPI_MSSEN
#define CONF_SERCOM_6_SPI_MSSEN 0x0
#endif
#ifndef CONF_SERCOM_6_SPI_PLOADEN
#define CONF_SERCOM_6_SPI_PLOADEN 0
#endif
// <o> Receive Data Pinout
// <0x0=>PAD[0]
// <0x1=>PAD[1]
// <0x2=>PAD[2]
// <0x3=>PAD[3]
// <id> spi_master_rxpo
#ifndef CONF_SERCOM_6_SPI_RXPO
#define CONF_SERCOM_6_SPI_RXPO 2
#endif
// <o> Transmit Data Pinout
// <0x0=>PAD[0,1]_DO_SCK
// <0x1=>PAD[2,3]_DO_SCK
// <0x2=>PAD[3,1]_DO_SCK
// <0x3=>PAD[0,3]_DO_SCK
// <id> spi_master_txpo
#ifndef CONF_SERCOM_6_SPI_TXPO
#define CONF_SERCOM_6_SPI_TXPO 0
#endif
// Calculate baud register value from requested baudrate value
#ifndef CONF_SERCOM_6_SPI_BAUD_RATE
#define CONF_SERCOM_6_SPI_BAUD_RATE ((float)CONF_GCLK_SERCOM6_CORE_FREQUENCY / (float)(2 * CONF_SERCOM_6_SPI_BAUD)) - 1
#endif
// <<< end of configuration section >>>
#endif // HPL_SERCOM_CONFIG_H