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ArduinoCore-samd/cores/arduino/SERCOM.cpp
hathach c8287a11c6
clean up format
2024-09-05 18:47:37 +07:00

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/*
Copyright (c) 2014 Arduino. All right reserved.
SAMD51 support added by Adafruit - Copyright (c) 2018 Dean Miller for Adafruit Industries
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include "SERCOM.h"
#include "variant.h"
#include "Arduino.h"
#ifndef WIRE_RISE_TIME_NANOSECONDS
// Default rise time in nanoseconds, based on 4.7K ohm pull up resistors
// you can override this value in your variant if needed
#define WIRE_RISE_TIME_NANOSECONDS 125
#endif
SERCOM::SERCOM(Sercom* s)
{
sercom = s;
#if defined(__SAMD51__)
// A briefly-available but now deprecated feature had the SPI clock source
// set via a compile-time setting (MAX_SPI)...problem was this affected
// ALL SERCOMs, whereas some (anything read/write, e.g. SD cards) should
// not exceed the standard 24 MHz setting. Newer code, if it needs faster
// write-only SPI (e.g. to screen), should override the SERCOM clock on a
// per-peripheral basis. Nonetheless, we check SERCOM_SPI_FREQ_REF here
// (MAX_SPI * 2) to retain compatibility with any interim projects that
// might have relied on the compile-time setting. But please, don't.
#if SERCOM_SPI_FREQ_REF == F_CPU // F_CPU clock = GCLK0
clockSource = SERCOM_CLOCK_SOURCE_FCPU;
#elif SERCOM_SPI_FREQ_REF == 48000000 // 48 MHz clock = GCLK1 (standard)
clockSource = SERCOM_CLOCK_SOURCE_48M;
#elif SERCOM_SPI_FREQ_REF == 100000000 // 100 MHz clock = GCLK2
clockSource = SERCOM_CLOCK_SOURCE_100M;
#endif
#endif // end __SAMD51__
}
/* =========================
* ===== Sercom UART
* =========================
*/
void SERCOM::initUART(SercomUartMode mode, SercomUartSampleRate sampleRate, uint32_t baudrate)
{
initClockNVIC();
resetUART();
//Setting the CTRLA register
sercom->USART.CTRLA.reg = SERCOM_USART_CTRLA_MODE(mode) |
SERCOM_USART_CTRLA_SAMPR(sampleRate);
//Setting the Interrupt register
sercom->USART.INTENSET.reg = SERCOM_USART_INTENSET_RXC | //Received complete
SERCOM_USART_INTENSET_ERROR; //All others errors
if ( mode == UART_INT_CLOCK )
{
uint16_t sampleRateValue;
if (sampleRate == SAMPLE_RATE_x16) {
sampleRateValue = 16;
} else {
sampleRateValue = 8;
}
// Asynchronous fractional mode (Table 24-2 in datasheet)
// BAUD = fref / (sampleRateValue * fbaud)
// (multiply by 8, to calculate fractional piece)
#if defined(__SAMD51__)
uint32_t baudTimes8 = (SERCOM_FREQ_REF * 8) / (sampleRateValue * baudrate);
#else
uint32_t baudTimes8 = (SystemCoreClock * 8) / (sampleRateValue * baudrate);
#endif
sercom->USART.BAUD.FRAC.FP = (baudTimes8 % 8);
sercom->USART.BAUD.FRAC.BAUD = (baudTimes8 / 8);
}
}
void SERCOM::initFrame(SercomUartCharSize charSize, SercomDataOrder dataOrder, SercomParityMode parityMode, SercomNumberStopBit nbStopBits)
{
//Setting the CTRLA register
sercom->USART.CTRLA.reg |=
SERCOM_USART_CTRLA_FORM((parityMode == SERCOM_NO_PARITY ? 0 : 1) ) |
dataOrder << SERCOM_USART_CTRLA_DORD_Pos;
//Setting the CTRLB register
sercom->USART.CTRLB.reg |= SERCOM_USART_CTRLB_CHSIZE(charSize) |
nbStopBits << SERCOM_USART_CTRLB_SBMODE_Pos |
(parityMode == SERCOM_NO_PARITY ? 0 : parityMode) <<
SERCOM_USART_CTRLB_PMODE_Pos; //If no parity use default value
}
void SERCOM::initPads(SercomUartTXPad txPad, SercomRXPad rxPad)
{
//Setting the CTRLA register
sercom->USART.CTRLA.reg |= SERCOM_USART_CTRLA_TXPO(txPad) |
SERCOM_USART_CTRLA_RXPO(rxPad);
// Enable Transceiver and Receiver
sercom->USART.CTRLB.reg |= SERCOM_USART_CTRLB_TXEN | SERCOM_USART_CTRLB_RXEN ;
}
void SERCOM::resetUART()
{
// Start the Software Reset
sercom->USART.CTRLA.bit.SWRST = 1 ;
while ( sercom->USART.CTRLA.bit.SWRST || sercom->USART.SYNCBUSY.bit.SWRST )
{
// Wait for both bits Software Reset from CTRLA and SYNCBUSY coming back to 0
}
}
void SERCOM::enableUART()
{
//Setting the enable bit to 1
sercom->USART.CTRLA.bit.ENABLE = 0x1u;
//Wait for then enable bit from SYNCBUSY is equal to 0;
while(sercom->USART.SYNCBUSY.bit.ENABLE);
}
void SERCOM::flushUART()
{
// Skip checking transmission completion if data register is empty
if(isDataRegisterEmptyUART())
return;
// Wait for transmission to complete
while(!sercom->USART.INTFLAG.bit.TXC);
}
void SERCOM::clearStatusUART()
{
//Reset (with 0) the STATUS register
sercom->USART.STATUS.reg = SERCOM_USART_STATUS_RESETVALUE;
}
bool SERCOM::availableDataUART()
{
//RXC : Receive Complete
return sercom->USART.INTFLAG.bit.RXC;
}
bool SERCOM::isUARTError()
{
return sercom->USART.INTFLAG.bit.ERROR;
}
void SERCOM::acknowledgeUARTError()
{
sercom->USART.INTFLAG.bit.ERROR = 1;
}
bool SERCOM::isBufferOverflowErrorUART()
{
//BUFOVF : Buffer Overflow
return sercom->USART.STATUS.bit.BUFOVF;
}
bool SERCOM::isFrameErrorUART()
{
//FERR : Frame Error
return sercom->USART.STATUS.bit.FERR;
}
void SERCOM::clearFrameErrorUART()
{
// clear FERR bit writing 1 status bit
sercom->USART.STATUS.bit.FERR = 1;
}
bool SERCOM::isParityErrorUART()
{
//PERR : Parity Error
return sercom->USART.STATUS.bit.PERR;
}
bool SERCOM::isDataRegisterEmptyUART()
{
//DRE : Data Register Empty
return sercom->USART.INTFLAG.bit.DRE;
}
uint8_t SERCOM::readDataUART()
{
return sercom->USART.DATA.bit.DATA;
}
int SERCOM::writeDataUART(uint8_t data)
{
// Wait for data register to be empty
while(!isDataRegisterEmptyUART());
//Put data into DATA register
sercom->USART.DATA.reg = (uint16_t)data;
return 1;
}
void SERCOM::enableDataRegisterEmptyInterruptUART()
{
sercom->USART.INTENSET.reg = SERCOM_USART_INTENSET_DRE;
}
void SERCOM::disableDataRegisterEmptyInterruptUART()
{
sercom->USART.INTENCLR.reg = SERCOM_USART_INTENCLR_DRE;
}
/* =========================
* ===== Sercom SPI
* =========================
*/
void SERCOM::initSPI(SercomSpiTXPad mosi, SercomRXPad miso, SercomSpiCharSize charSize, SercomDataOrder dataOrder)
{
resetSPI();
initClockNVIC();
#if defined(__SAMD51__)
sercom->SPI.CTRLA.reg = SERCOM_SPI_CTRLA_MODE(0x3) | // master mode
SERCOM_SPI_CTRLA_DOPO(mosi) |
SERCOM_SPI_CTRLA_DIPO(miso) |
dataOrder << SERCOM_SPI_CTRLA_DORD_Pos;
#else
//Setting the CTRLA register
sercom->SPI.CTRLA.reg = SERCOM_SPI_CTRLA_MODE_SPI_MASTER |
SERCOM_SPI_CTRLA_DOPO(mosi) |
SERCOM_SPI_CTRLA_DIPO(miso) |
dataOrder << SERCOM_SPI_CTRLA_DORD_Pos;
#endif
//Setting the CTRLB register
sercom->SPI.CTRLB.reg = SERCOM_SPI_CTRLB_CHSIZE(charSize) |
SERCOM_SPI_CTRLB_RXEN; //Active the SPI receiver.
while( sercom->SPI.SYNCBUSY.bit.CTRLB == 1 );
}
void SERCOM::initSPIClock(SercomSpiClockMode clockMode, uint32_t baudrate)
{
//Extract data from clockMode
int cpha, cpol;
if((clockMode & (0x1ul)) == 0 )
cpha = 0;
else
cpha = 1;
if((clockMode & (0x2ul)) == 0)
cpol = 0;
else
cpol = 1;
//Setting the CTRLA register
sercom->SPI.CTRLA.reg |= ( cpha << SERCOM_SPI_CTRLA_CPHA_Pos ) |
( cpol << SERCOM_SPI_CTRLA_CPOL_Pos );
//Synchronous arithmetic
sercom->SPI.BAUD.reg = calculateBaudrateSynchronous(baudrate);
}
void SERCOM::resetSPI()
{
//Setting the Software Reset bit to 1
sercom->SPI.CTRLA.bit.SWRST = 1;
//Wait both bits Software Reset from CTRLA and SYNCBUSY are equal to 0
while(sercom->SPI.CTRLA.bit.SWRST || sercom->SPI.SYNCBUSY.bit.SWRST);
}
void SERCOM::enableSPI()
{
//Setting the enable bit to 1
sercom->SPI.CTRLA.bit.ENABLE = 1;
while(sercom->SPI.SYNCBUSY.bit.ENABLE)
{
//Waiting then enable bit from SYNCBUSY is equal to 0;
}
}
void SERCOM::disableSPI()
{
while(sercom->SPI.SYNCBUSY.bit.ENABLE)
{
//Waiting then enable bit from SYNCBUSY is equal to 0;
}
//Setting the enable bit to 0
sercom->SPI.CTRLA.bit.ENABLE = 0;
}
void SERCOM::setDataOrderSPI(SercomDataOrder dataOrder)
{
//Register enable-protected
disableSPI();
sercom->SPI.CTRLA.bit.DORD = dataOrder;
enableSPI();
}
SercomDataOrder SERCOM::getDataOrderSPI()
{
return (sercom->SPI.CTRLA.bit.DORD ? LSB_FIRST : MSB_FIRST);
}
void SERCOM::setBaudrateSPI(uint8_t divider)
{
disableSPI(); // Register is enable-protected
#if defined(__SAMD51__)
sercom->SPI.BAUD.reg = calculateBaudrateSynchronous(freqRef / divider);
#else
sercom->SPI.BAUD.reg = calculateBaudrateSynchronous(SERCOM_SPI_FREQ_REF / divider);
#endif
enableSPI();
}
void SERCOM::setClockModeSPI(SercomSpiClockMode clockMode)
{
int cpha, cpol;
if((clockMode & (0x1ul)) == 0)
cpha = 0;
else
cpha = 1;
if((clockMode & (0x2ul)) == 0)
cpol = 0;
else
cpol = 1;
//Register enable-protected
disableSPI();
sercom->SPI.CTRLA.bit.CPOL = cpol;
sercom->SPI.CTRLA.bit.CPHA = cpha;
enableSPI();
}
uint8_t SERCOM::transferDataSPI(uint8_t data)
{
sercom->SPI.DATA.bit.DATA = data; // Writing data into Data register
while(sercom->SPI.INTFLAG.bit.RXC == 0); // Waiting Complete Reception
return sercom->SPI.DATA.bit.DATA; // Reading data
}
bool SERCOM::isBufferOverflowErrorSPI()
{
return sercom->SPI.STATUS.bit.BUFOVF;
}
bool SERCOM::isDataRegisterEmptySPI()
{
//DRE : Data Register Empty
return sercom->SPI.INTFLAG.bit.DRE;
}
//bool SERCOM::isTransmitCompleteSPI()
//{
// //TXC : Transmit complete
// return sercom->SPI.INTFLAG.bit.TXC;
//}
//
//bool SERCOM::isReceiveCompleteSPI()
//{
// //RXC : Receive complete
// return sercom->SPI.INTFLAG.bit.RXC;
//}
uint8_t SERCOM::calculateBaudrateSynchronous(uint32_t baudrate) {
#if defined(__SAMD51__)
uint16_t b = freqRef / (2 * baudrate);
#else
uint16_t b = SERCOM_SPI_FREQ_REF / (2 * baudrate);
#endif
if(b > 0) b--; // Don't -1 on baud calc if already at 0
return b;
}
/* =========================
* ===== Sercom WIRE
* =========================
*/
void SERCOM::resetWIRE()
{
//I2CM OR I2CS, no matter SWRST is the same bit.
//Setting the Software bit to 1
sercom->I2CM.CTRLA.bit.SWRST = 1;
//Wait both bits Software Reset from CTRLA and SYNCBUSY are equal to 0
while(sercom->I2CM.CTRLA.bit.SWRST || sercom->I2CM.SYNCBUSY.bit.SWRST);
}
void SERCOM::enableWIRE()
{
// I2C Master and Slave modes share the ENABLE bit function.
// Enable the I2C master mode
sercom->I2CM.CTRLA.bit.ENABLE = 1 ;
while ( sercom->I2CM.SYNCBUSY.bit.ENABLE != 0 )
{
// Waiting the enable bit from SYNCBUSY is equal to 0;
}
// Setting bus idle mode
sercom->I2CM.STATUS.bit.BUSSTATE = 1 ;
while ( sercom->I2CM.SYNCBUSY.bit.SYSOP != 0 )
{
// Wait the SYSOP bit from SYNCBUSY coming back to 0
}
}
void SERCOM::disableWIRE()
{
// I2C Master and Slave modes share the ENABLE bit function.
// Enable the I2C master mode
sercom->I2CM.CTRLA.bit.ENABLE = 0 ;
while ( sercom->I2CM.SYNCBUSY.bit.ENABLE != 0 )
{
// Waiting the enable bit from SYNCBUSY is equal to 0;
}
}
void SERCOM::initSlaveWIRE( uint8_t ucAddress, bool enableGeneralCall )
{
// Initialize the peripheral clock and interruption
initClockNVIC() ;
resetWIRE() ;
// Set slave mode
sercom->I2CS.CTRLA.bit.MODE = I2C_SLAVE_OPERATION;
sercom->I2CS.ADDR.reg = SERCOM_I2CS_ADDR_ADDR( ucAddress & 0x7Ful ) | // 0x7F, select only 7 bits
SERCOM_I2CS_ADDR_ADDRMASK( 0x00ul ); // 0x00, only match exact address
if (enableGeneralCall) {
sercom->I2CS.ADDR.reg |= SERCOM_I2CS_ADDR_GENCEN; // enable general call (address 0x00)
}
// Set the interrupt register
sercom->I2CS.INTENSET.reg = SERCOM_I2CS_INTENSET_PREC | // Stop
SERCOM_I2CS_INTENSET_AMATCH | // Address Match
SERCOM_I2CS_INTENSET_DRDY ; // Data Ready
while ( sercom->I2CM.SYNCBUSY.bit.SYSOP != 0 )
{
// Wait the SYSOP bit from SYNCBUSY to come back to 0
}
}
void SERCOM::initMasterWIRE( uint32_t baudrate )
{
// Initialize the peripheral clock and interruption
initClockNVIC() ;
resetWIRE() ;
// Set master mode and enable SCL Clock Stretch mode (stretch after ACK bit)
sercom->I2CM.CTRLA.reg = SERCOM_I2CM_CTRLA_MODE( I2C_MASTER_OPERATION )/* |
SERCOM_I2CM_CTRLA_SCLSM*/ ;
// Enable Smart mode and Quick Command
//sercom->I2CM.CTRLB.reg = SERCOM_I2CM_CTRLB_SMEN /*| SERCOM_I2CM_CTRLB_QCEN*/ ;
// Enable all interrupts
// sercom->I2CM.INTENSET.reg = SERCOM_I2CM_INTENSET_MB | SERCOM_I2CM_INTENSET_SB | SERCOM_I2CM_INTENSET_ERROR ;
// Synchronous arithmetic baudrate
#if defined(__SAMD51__)
sercom->I2CM.BAUD.bit.BAUD = SERCOM_FREQ_REF / ( 2 * baudrate) - 1 ;
#else
sercom->I2CM.BAUD.bit.BAUD = SystemCoreClock / ( 2 * baudrate) - 5 - (((SystemCoreClock / 1000000) * WIRE_RISE_TIME_NANOSECONDS) / (2 * 1000));
#endif
}
void SERCOM::prepareNackBitWIRE( void )
{
if(isMasterWIRE()) {
// Send a NACK
sercom->I2CM.CTRLB.bit.ACKACT = 1;
} else {
sercom->I2CS.CTRLB.bit.ACKACT = 1;
}
}
void SERCOM::prepareAckBitWIRE( void )
{
if(isMasterWIRE()) {
// Send an ACK
sercom->I2CM.CTRLB.bit.ACKACT = 0;
} else {
sercom->I2CS.CTRLB.bit.ACKACT = 0;
}
}
void SERCOM::prepareCommandBitsWire(uint8_t cmd)
{
if(isMasterWIRE()) {
sercom->I2CM.CTRLB.bit.CMD = cmd;
while(sercom->I2CM.SYNCBUSY.bit.SYSOP)
{
// Waiting for synchronization
}
} else {
sercom->I2CS.CTRLB.bit.CMD = cmd;
}
}
bool SERCOM::startTransmissionWIRE(uint8_t address, SercomWireReadWriteFlag flag)
{
// 7-bits address + 1-bits R/W
address = (address << 0x1ul) | flag;
// If another master owns the bus or the last bus owner has not properly
// sent a stop, return failure early. This will prevent some misbehaved
// devices from deadlocking here at the cost of the caller being responsible
// for retrying the failed transmission. See SercomWireBusState for the
// possible bus states.
if(!isBusOwnerWIRE())
{
if( isBusBusyWIRE() || (isArbLostWIRE() && !isBusIdleWIRE()) || isBusUnknownWIRE() )
{
return false;
}
}
// Send start and address
sercom->I2CM.ADDR.bit.ADDR = address;
// Address Transmitted
if ( flag == WIRE_WRITE_FLAG ) // Write mode
{
while( !sercom->I2CM.INTFLAG.bit.MB ) {
// Wait transmission complete
// If certain errors occur, the MB bit may never be set (RFTM: SAMD21 sec:28.10.6; SAMD51 sec:36.10.7).
// The data transfer errors that can occur (including BUSERR) are all
// rolled up into INTFLAG.bit.ERROR from STATUS.reg
if (sercom->I2CM.INTFLAG.bit.ERROR) {
return false;
}
}
}
else // Read mode
{
while( !sercom->I2CM.INTFLAG.bit.SB ) {
// Wait transmission complete
// If the slave NACKS the address, the MB bit will be set.
// A variety of errors in the STATUS register can set the ERROR bit in the INTFLAG register
// In that case, send a stop condition and return false.
if (sercom->I2CM.INTFLAG.bit.MB || sercom->I2CM.INTFLAG.bit.ERROR) {
sercom->I2CM.CTRLB.bit.CMD = 3; // Stop condition
return false;
}
}
// Clean the 'Slave on Bus' flag, for further usage.
//sercom->I2CM.INTFLAG.bit.SB = 0x1ul;
}
//ACK received (0: ACK, 1: NACK)
if(sercom->I2CM.STATUS.bit.RXNACK)
{
return false;
}
else
{
return true;
}
}
bool SERCOM::sendDataMasterWIRE(uint8_t data)
{
//Send data
sercom->I2CM.DATA.bit.DATA = data;
//Wait transmission successful
while(!sercom->I2CM.INTFLAG.bit.MB) {
// If a data transfer error occurs, the MB bit may never be set.
// Check the error bit and bail if it's set.
// The data transfer errors that can occur (including BUSERR) are all
// rolled up into INTFLAG.bit.ERROR from STATUS.reg
if (sercom->I2CM.INTFLAG.bit.ERROR) {
return false;
}
}
//Problems on line? nack received?
if(sercom->I2CM.STATUS.bit.RXNACK)
return false;
else
return true;
}
bool SERCOM::sendDataSlaveWIRE(uint8_t data)
{
//Send data
sercom->I2CS.DATA.bit.DATA = data;
//Problems on line? nack received?
if(!sercom->I2CS.INTFLAG.bit.DRDY || sercom->I2CS.STATUS.bit.RXNACK)
return false;
else
return true;
}
bool SERCOM::isMasterWIRE( void )
{
return sercom->I2CS.CTRLA.bit.MODE == I2C_MASTER_OPERATION;
}
bool SERCOM::isSlaveWIRE( void )
{
return sercom->I2CS.CTRLA.bit.MODE == I2C_SLAVE_OPERATION;
}
bool SERCOM::isBusIdleWIRE( void )
{
return sercom->I2CM.STATUS.bit.BUSSTATE == WIRE_IDLE_STATE;
}
bool SERCOM::isBusOwnerWIRE( void )
{
return sercom->I2CM.STATUS.bit.BUSSTATE == WIRE_OWNER_STATE;
}
bool SERCOM::isBusUnknownWIRE( void )
{
return sercom->I2CM.STATUS.bit.BUSSTATE == WIRE_UNKNOWN_STATE;
}
bool SERCOM::isArbLostWIRE( void )
{
return sercom->I2CM.STATUS.bit.ARBLOST == 1;
}
bool SERCOM::isBusBusyWIRE( void )
{
return sercom->I2CM.STATUS.bit.BUSSTATE == WIRE_BUSY_STATE;
}
bool SERCOM::isDataReadyWIRE( void )
{
return sercom->I2CS.INTFLAG.bit.DRDY;
}
bool SERCOM::isStopDetectedWIRE( void )
{
return sercom->I2CS.INTFLAG.bit.PREC;
}
bool SERCOM::isRestartDetectedWIRE( void )
{
return sercom->I2CS.STATUS.bit.SR;
}
bool SERCOM::isAddressMatch( void )
{
return sercom->I2CS.INTFLAG.bit.AMATCH;
}
bool SERCOM::isMasterReadOperationWIRE( void )
{
return sercom->I2CS.STATUS.bit.DIR;
}
bool SERCOM::isRXNackReceivedWIRE( void )
{
return sercom->I2CM.STATUS.bit.RXNACK;
}
int SERCOM::availableWIRE( void )
{
if(isMasterWIRE())
return sercom->I2CM.INTFLAG.bit.SB;
else
return sercom->I2CS.INTFLAG.bit.DRDY;
}
uint8_t SERCOM::readDataWIRE( void )
{
if(isMasterWIRE())
{
while (sercom->I2CM.INTFLAG.bit.SB == 0) {
// Waiting complete receive
// A variety of errors in the STATUS register can set the ERROR bit in the INTFLAG register
// In that case, send a stop condition and return false.
// readDataWIRE should really be able to indicate an error (which would never be used
// because the readDataWIRE callers (in Wire.cpp) should have checked availableWIRE() first and timed it
// out if the data never showed up
if (sercom->I2CM.INTFLAG.bit.MB || sercom->I2CM.INTFLAG.bit.ERROR) {
sercom->I2CM.CTRLB.bit.CMD = 3; // Stop condition
return 0xFF;
}
}
return sercom->I2CM.DATA.bit.DATA ;
}
else
{
return sercom->I2CS.DATA.reg ;
}
}
#if defined(__SAMD51__)
static const struct {
Sercom *sercomPtr;
uint8_t id_core;
uint8_t id_slow;
IRQn_Type irq[4];
} sercomData[] = {
{ SERCOM0, SERCOM0_GCLK_ID_CORE, SERCOM0_GCLK_ID_SLOW,
SERCOM0_0_IRQn, SERCOM0_1_IRQn, SERCOM0_2_IRQn, SERCOM0_3_IRQn },
{ SERCOM1, SERCOM1_GCLK_ID_CORE, SERCOM1_GCLK_ID_SLOW,
SERCOM1_0_IRQn, SERCOM1_1_IRQn, SERCOM1_2_IRQn, SERCOM1_3_IRQn },
{ SERCOM2, SERCOM2_GCLK_ID_CORE, SERCOM2_GCLK_ID_SLOW,
SERCOM2_0_IRQn, SERCOM2_1_IRQn, SERCOM2_2_IRQn, SERCOM2_3_IRQn },
{ SERCOM3, SERCOM3_GCLK_ID_CORE, SERCOM3_GCLK_ID_SLOW,
SERCOM3_0_IRQn, SERCOM3_1_IRQn, SERCOM3_2_IRQn, SERCOM3_3_IRQn },
{ SERCOM4, SERCOM4_GCLK_ID_CORE, SERCOM4_GCLK_ID_SLOW,
SERCOM4_0_IRQn, SERCOM4_1_IRQn, SERCOM4_2_IRQn, SERCOM4_3_IRQn },
{ SERCOM5, SERCOM5_GCLK_ID_CORE, SERCOM5_GCLK_ID_SLOW,
SERCOM5_0_IRQn, SERCOM5_1_IRQn, SERCOM5_2_IRQn, SERCOM5_3_IRQn },
#if defined(SERCOM6)
{ SERCOM6, SERCOM6_GCLK_ID_CORE, SERCOM6_GCLK_ID_SLOW,
SERCOM6_0_IRQn, SERCOM6_1_IRQn, SERCOM6_2_IRQn, SERCOM6_3_IRQn },
#endif
#if defined(SERCOM7)
{ SERCOM7, SERCOM7_GCLK_ID_CORE, SERCOM7_GCLK_ID_SLOW,
SERCOM7_0_IRQn, SERCOM7_1_IRQn, SERCOM7_2_IRQn, SERCOM7_3_IRQn },
#endif
};
#else // end if SAMD51 (prob SAMD21)
static const struct {
Sercom *sercomPtr;
uint8_t clock;
IRQn_Type irqn;
} sercomData[] = {
SERCOM0, GCM_SERCOM0_CORE, SERCOM0_IRQn,
SERCOM1, GCM_SERCOM1_CORE, SERCOM1_IRQn,
SERCOM2, GCM_SERCOM2_CORE, SERCOM2_IRQn,
SERCOM3, GCM_SERCOM3_CORE, SERCOM3_IRQn,
#if defined(SERCOM4)
SERCOM4, GCM_SERCOM4_CORE, SERCOM4_IRQn,
#endif
#if defined(SERCOM5)
SERCOM5, GCM_SERCOM5_CORE, SERCOM5_IRQn,
#endif
};
#endif // end !SAMD51
int8_t SERCOM::getSercomIndex(void) {
for(uint8_t i=0; i<(sizeof(sercomData) / sizeof(sercomData[0])); i++) {
if(sercom == sercomData[i].sercomPtr) return i;
}
return -1;
}
#if defined(__SAMD51__)
// This is currently for overriding an SPI SERCOM's clock source only --
// NOT for UART or WIRE SERCOMs, where it will have unintended consequences.
// It does not check.
// SERCOM clock source override is available only on SAMD51 (not 21).
// A dummy function for SAMD21 (compiles to nothing) is present in SERCOM.h
// so user code doesn't require a lot of conditional situations.
void SERCOM::setClockSource(int8_t idx, SercomClockSource src, bool core) {
if(src == SERCOM_CLOCK_SOURCE_NO_CHANGE) return;
uint8_t clk_id = core ? sercomData[idx].id_core : sercomData[idx].id_slow;
GCLK->PCHCTRL[clk_id].bit.CHEN = 0; // Disable timer
while(GCLK->PCHCTRL[clk_id].bit.CHEN); // Wait for disable
if(core) clockSource = src; // Save SercomClockSource value
// From cores/arduino/startup.c:
// GCLK0 = F_CPU
// GCLK1 = 48 MHz
// GCLK2 = 100 MHz
// GCLK3 = XOSC32K
// GCLK4 = 12 MHz
if(src == SERCOM_CLOCK_SOURCE_FCPU) {
GCLK->PCHCTRL[clk_id].reg =
GCLK_PCHCTRL_GEN_GCLK0_Val | (1 << GCLK_PCHCTRL_CHEN_Pos);
if(core) freqRef = F_CPU; // Save clock frequency value
} else if(src == SERCOM_CLOCK_SOURCE_48M) {
GCLK->PCHCTRL[clk_id].reg =
GCLK_PCHCTRL_GEN_GCLK1_Val | (1 << GCLK_PCHCTRL_CHEN_Pos);
if(core) freqRef = 48000000;
} else if(src == SERCOM_CLOCK_SOURCE_100M) {
GCLK->PCHCTRL[clk_id].reg =
GCLK_PCHCTRL_GEN_GCLK2_Val | (1 << GCLK_PCHCTRL_CHEN_Pos);
if(core) freqRef = 100000000;
} else if(src == SERCOM_CLOCK_SOURCE_32K) {
GCLK->PCHCTRL[clk_id].reg =
GCLK_PCHCTRL_GEN_GCLK3_Val | (1 << GCLK_PCHCTRL_CHEN_Pos);
if(core) freqRef = 32768;
} else if(src == SERCOM_CLOCK_SOURCE_12M) {
GCLK->PCHCTRL[clk_id].reg =
GCLK_PCHCTRL_GEN_GCLK4_Val | (1 << GCLK_PCHCTRL_CHEN_Pos);
if(core) freqRef = 12000000;
}
while(!GCLK->PCHCTRL[clk_id].bit.CHEN); // Wait for clock enable
}
#endif
void SERCOM::initClockNVIC( void )
{
int8_t idx = getSercomIndex();
if(idx < 0) return; // We got a problem here
#if defined(__SAMD51__)
for(uint8_t i=0; i<4; i++) {
NVIC_ClearPendingIRQ(sercomData[idx].irq[i]);
NVIC_SetPriority(sercomData[idx].irq[i], SERCOM_NVIC_PRIORITY);
NVIC_EnableIRQ(sercomData[idx].irq[i]);
}
// SPI DMA speed is dictated by the "slow clock" (I think...maybe) so
// BOTH are set to the same clock source (clk_slow isn't sourced from
// XOSC32K as in prior versions of SAMD core).
// This might have power implications for sleep code.
setClockSource(idx, clockSource, true); // true = core clock
setClockSource(idx, clockSource, false); // false = slow clock
#else // end if SAMD51 (prob SAMD21)
uint8_t clockId = sercomData[idx].clock;
IRQn_Type IdNvic = sercomData[idx].irqn;
// Setting NVIC
NVIC_ClearPendingIRQ(IdNvic);
NVIC_SetPriority(IdNvic, SERCOM_NVIC_PRIORITY);
NVIC_EnableIRQ(IdNvic);
// Setting clock
GCLK->CLKCTRL.reg =
GCLK_CLKCTRL_ID( clockId ) | // Generic Clock 0 (SERCOMx)
GCLK_CLKCTRL_GEN_GCLK0 | // Generic Clock Generator 0 is source
GCLK_CLKCTRL_CLKEN;
while(GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY); // Wait for synchronization
#endif // end !SAMD51
}
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