/* ---------------------------------------------------------------------------- * SAM Software Package License * ---------------------------------------------------------------------------- * Copyright (c) 2011, Atmel Corporation * * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * - Redistributions of source code must retain the above copyright notice, * this list of conditions and the disclaimer below. * * Atmel's name may not be used to endorse or promote products derived from * this software without specific prior written permission. * * DISCLAIMER: THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE * DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, * OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, * EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * ---------------------------------------------------------------------------- */ /** \addtogroup twi_module Working with TWI * The TWI driver provides the interface to configure and use the TWI * peripheral. * * \section Usage * * 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 #include /*---------------------------------------------------------------------------- * 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<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; }