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/** \addtogroup twi_module Working with TWI
 * The TWI driver provides the interface to configure and use the TWI
 * peripheral.
 *
 * \section Usage
 * <ul>
 * <li> Configures a TWI peripheral to operate in master mode, at the given
 * frequency (in Hz) using TWI_Configure(). </li>
 * <li> Sends a STOP condition on the TWI using TWI_Stop().</li>
 * <li> Starts a read operation on the TWI bus with the specified slave using
 * TWI_StartRead(). Data must then be read using TWI_ReadByte() whenever
 * a byte is available (poll using TWI_ByteReceived()).</li>
 * <li> Starts a write operation on the TWI to access the selected slave using
 * TWI_StartWrite(). A byte of data must be provided to start the write;
 * other bytes are written next.</li>
 * <li> Sends a byte of data to one of the TWI slaves on the bus using TWI_WriteByte().
 * This function must be called once before TWI_StartWrite() with the first byte of data
 * to send, then it shall be called repeatedly after that to send the remaining bytes.</li>
 * <li> Check if a byte has been received and can be read on the given TWI
 * peripheral using TWI_ByteReceived().<
 * Check if a byte has been sent using TWI_ByteSent().</li>
 * <li> Check if the current transmission is complete (the STOP has been sent)
 * using TWI_TransferComplete().</li>
 * <li> Enables & disable the selected interrupts sources on a TWI peripheral
 * using TWI_EnableIt() and TWI_DisableIt().</li>
 * <li> Get current status register of the given TWI peripheral using
 * TWI_GetStatus(). Get current status register of the given TWI peripheral, but
 * masking interrupt sources which are not currently enabled using
 * TWI_GetMaskedStatus().</li>
 * </ul>
 * For more accurate information, please look at the TWI section of the
 * Datasheet.
 *
 * Related files :\n
 * \ref twi.c\n
 * \ref twi.h.\n
*/
/*@{*/
/*@}*/

/**
 * \file
 *
 * Implementation of Two Wire Interface (TWI).
 *
 */

/*----------------------------------------------------------------------------
 *        Headers
 *----------------------------------------------------------------------------*/

#include "chip.h"

#include <stdlib.h>
#include <assert.h>

/*----------------------------------------------------------------------------
 *        Exported functions
 *----------------------------------------------------------------------------*/

/**
 * \brief Configures a TWI peripheral to operate in master mode, at the given
 * frequency (in Hz). The duty cycle of the TWI clock is set to 50%.
 * \param pTwi  Pointer to an Twi instance.
 * \param twck  Desired TWI clock frequency.
 * \param mck  Master clock frequency.
 */
void TWI_ConfigureMaster( Twi* pTwi, uint32_t dwTwCk, uint32_t dwMCk )
{
    uint32_t dwCkDiv = 0 ;
    uint32_t dwClDiv ;
    uint32_t dwOk = 0 ;

    assert( pTwi ) ;

    /* SVEN: TWI Slave Mode Enabled */
    pTwi->TWI_CR = TWI_CR_SVEN ;
    /* Reset the TWI */
    pTwi->TWI_CR = TWI_CR_SWRST ;
    pTwi->TWI_RHR ;

    /* TWI Slave Mode Disabled, TWI Master Mode Disabled. */
    pTwi->TWI_CR = TWI_CR_SVDIS ;
    pTwi->TWI_CR = TWI_CR_MSDIS ;

    /* Set master mode */
    pTwi->TWI_CR = TWI_CR_MSEN ;

    /* Configure clock */
    while ( !dwOk )
    {
        dwClDiv = ((dwMCk / (2 * dwTwCk)) - 4) / (1<<dwCkDiv) ;

        if ( dwClDiv <= 255 )
        {
            dwOk = 1 ;
        }
        else
        {
            dwCkDiv++ ;
        }
    }

    assert( dwCkDiv < 8 ) ;
//    TRACE_DEBUG( "Using CKDIV = %u and CLDIV/CHDIV = %u\n\r", dwCkDiv, dwClDiv ) ;

    pTwi->TWI_CWGR = 0 ;
    pTwi->TWI_CWGR = (dwCkDiv << 16) | (dwClDiv << 8) | dwClDiv ;
}

/**
 * \brief Configures a TWI peripheral to operate in slave mode.
 * \param pTwi  Pointer to an Twi instance.
 * \param slaveAddress Slave address.
 */
void TWI_ConfigureSlave(Twi *pTwi, uint8_t slaveAddress)
{
    uint32_t i;

    /* TWI software reset */
    pTwi->TWI_CR = TWI_CR_SWRST;
    pTwi->TWI_RHR;

    /* Wait at least 10 ms */
    for (i=0; i < 1000000; i++);

    /* TWI Slave Mode Disabled, TWI Master Mode Disabled*/
    pTwi->TWI_CR = TWI_CR_SVDIS | TWI_CR_MSDIS;

    /* Configure slave address. */
    pTwi->TWI_SMR = 0;
    pTwi->TWI_SMR = TWI_SMR_SADR(slaveAddress);

    /* SVEN: TWI Slave Mode Enabled */
    pTwi->TWI_CR = TWI_CR_SVEN;

    /* Wait at least 10 ms */
    for (i=0; i < 1000000; i++);
    assert( (pTwi->TWI_CR & TWI_CR_SVDIS)!= TWI_CR_SVDIS ) ;
}

/**
 * \brief Sends a STOP condition on the TWI.
 * \param pTwi  Pointer to an Twi instance.
 */
void TWI_Stop( Twi *pTwi )
{
    assert( pTwi != NULL ) ;

    pTwi->TWI_CR = TWI_CR_STOP;
}

/**
 * \brief Starts a read operation on the TWI bus with the specified slave, it returns
 * immediately. Data must then be read using TWI_ReadByte() whenever a byte is
 * available (poll using TWI_ByteReceived()).
 * \param pTwi  Pointer to an Twi instance.
 * \param address  Slave address on the bus.
 * \param iaddress  Optional internal address bytes.
 * \param isize  Number of internal address bytes.
 */
void TWI_StartRead(
    Twi *pTwi,
    uint8_t address,
    uint32_t iaddress,
    uint8_t isize)
{
    assert( pTwi != NULL ) ;
    assert( (address & 0x80) == 0 ) ;
    assert( (iaddress & 0xFF000000) == 0 ) ;
    assert( isize < 4 ) ;

    /* Set slave address and number of internal address bytes. */
    pTwi->TWI_MMR = 0;
    pTwi->TWI_MMR = (isize << 8) | TWI_MMR_MREAD | (address << 16);

    /* Set internal address bytes */
    pTwi->TWI_IADR = 0;
    pTwi->TWI_IADR = iaddress;

    /* Send START condition */
    pTwi->TWI_CR = TWI_CR_START;
}

/**
 * \brief Reads a byte from the TWI bus. The read operation must have been started
 * using TWI_StartRead() and a byte must be available (check with TWI_ByteReceived()).
 * \param pTwi  Pointer to an Twi instance.
 * \return byte read.
 */
uint8_t TWI_ReadByte(Twi *pTwi)
{
    assert( pTwi != NULL ) ;

    return pTwi->TWI_RHR;
}

/**
 * \brief Sends a byte of data to one of the TWI slaves on the bus.
 * \note This function must be called once before TWI_StartWrite() with
 * the first byte of data  to send, then it shall be called repeatedly
 * after that to send the remaining bytes.
 * \param pTwi  Pointer to an Twi instance.
 * \param byte  Byte to send.
 */
void TWI_WriteByte(Twi *pTwi, uint8_t byte)
{
    assert( pTwi != NULL ) ;

    pTwi->TWI_THR = byte;
}

/**
 * \brief Starts a write operation on the TWI to access the selected slave, then
 *  returns immediately. A byte of data must be provided to start the write;
 * other bytes are written next.
 * after that to send the remaining bytes.
 * \param pTwi  Pointer to an Twi instance.
 * \param address  Address of slave to acccess on the bus.
 * \param iaddress  Optional slave internal address.
 * \param isize  Number of internal address bytes.
 * \param byte  First byte to send.
 */
void TWI_StartWrite(
    Twi *pTwi,
    uint8_t address,
    uint32_t iaddress,
    uint8_t isize,
    uint8_t byte)
{
    assert( pTwi != NULL ) ;
    assert( (address & 0x80) == 0 ) ;
    assert( (iaddress & 0xFF000000) == 0 ) ;
    assert( isize < 4 ) ;

    /* Set slave address and number of internal address bytes. */
    pTwi->TWI_MMR = 0;
    pTwi->TWI_MMR = (isize << 8) | (address << 16);

    /* Set internal address bytes. */
    pTwi->TWI_IADR = 0;
    pTwi->TWI_IADR = iaddress;

    /* Write first byte to send.*/
    TWI_WriteByte(pTwi, byte);
}

/**
 * \brief Check if a byte have been receiced from TWI.
 * \param pTwi  Pointer to an Twi instance.
 * \return 1 if a byte has been received and can be read on the given TWI
 * peripheral; otherwise, returns 0. This function resets the status register.
 */
uint8_t TWI_ByteReceived(Twi *pTwi)
{
    return ((pTwi->TWI_SR & TWI_SR_RXRDY) == TWI_SR_RXRDY);
}

/**
 * \brief Check if a byte have been sent to TWI.
 * \param pTwi  Pointer to an Twi instance.
 * \return 1 if a byte has been sent  so another one can be stored for
 * transmission; otherwise returns 0. This function clears the status register.
 */
uint8_t TWI_ByteSent(Twi *pTwi)
{
    return ((pTwi->TWI_SR & TWI_SR_TXRDY) == TWI_SR_TXRDY);
}

/**
 * \brief Check if current transmission is complet.
 * \param pTwi  Pointer to an Twi instance.
 * \return  1 if the current transmission is complete (the STOP has been sent);
 * otherwise returns 0.
 */
uint8_t TWI_TransferComplete(Twi *pTwi)
{
    return ((pTwi->TWI_SR & TWI_SR_TXCOMP) == TWI_SR_TXCOMP);
}

/**
 * \brief Enables the selected interrupts sources on a TWI peripheral.
 * \param pTwi  Pointer to an Twi instance.
 * \param sources  Bitwise OR of selected interrupt sources.
 */
void TWI_EnableIt(Twi *pTwi, uint32_t sources)
{
    assert( pTwi != NULL ) ;
    assert( (sources & 0xFFFFF088) == 0 ) ;

    pTwi->TWI_IER = sources;
}

/**
 * \brief Disables the selected interrupts sources on a TWI peripheral.
 * \param pTwi  Pointer to an Twi instance.
 * \param sources  Bitwise OR of selected interrupt sources.
 */
void TWI_DisableIt(Twi *pTwi, uint32_t sources)
{
    assert( pTwi != NULL ) ;
    assert( (sources & 0xFFFFF088) == 0 ) ;

    pTwi->TWI_IDR = sources;
}

/**
 * \brief Get the current status register of the given TWI peripheral.
 * \note This resets the internal value of the status register, so further
 * read may yield different values.
 * \param pTwi  Pointer to an Twi instance.
 * \return  TWI status register.
 */
uint32_t TWI_GetStatus(Twi *pTwi)
{
    assert( pTwi != NULL ) ;

    return pTwi->TWI_SR;
}

/**
 * \brief Returns the current status register of the given TWI peripheral, but
 * masking interrupt sources which are not currently enabled.
 * \note This resets the internal value of the status register, so further
 * read may yield different values.
 * \param pTwi  Pointer to an Twi instance.
 */
uint32_t TWI_GetMaskedStatus(Twi *pTwi)
{
    uint32_t status;

    assert( pTwi != NULL ) ;

    status = pTwi->TWI_SR;
    status &= pTwi->TWI_IMR;

    return status;
}

/**
 * \brief  Sends a STOP condition. STOP Condition is sent just after completing
 *  the current byte transmission in master read mode.
 * \param pTwi  Pointer to an Twi instance.
 */
void TWI_SendSTOPCondition(Twi *pTwi)
{
    assert( pTwi != NULL ) ;

    pTwi->TWI_CR |= TWI_CR_STOP;
}