FreeRTOSV8.0.1/FreeRTOS/Demo/CORTEX_AT91SAM3U256_IAR/AT91Lib/peripherals/mci/mci.c - nest-detect/1.0/freertos - Git at Google

 /* ----------------------------------------------------------------------------
  *         ATMEL Microcontroller Software Support
  * ----------------------------------------------------------------------------
  * Copyright (c) 2008, 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.
  * ----------------------------------------------------------------------------
  */

 //------------------------------------------------------------------------------
 //         Headers
 //------------------------------------------------------------------------------

 #include "mci.h"
 #include <utility/assert.h>
 #include <utility/trace.h>

 //------------------------------------------------------------------------------
 //         Local constants
 //------------------------------------------------------------------------------

 /// Bit mask for status register errors.
 #define STATUS_ERRORS (AT91C_MCI_UNRE  \
                        | AT91C_MCI_OVRE \
                        | AT91C_MCI_DTOE \
                        | AT91C_MCI_DCRCE \
                        | AT91C_MCI_RTOE \
                        | AT91C_MCI_RENDE \
                        | AT91C_MCI_RCRCE \
                        | AT91C_MCI_RDIRE \
                        | AT91C_MCI_RINDE)

 /// MCI data timeout configuration with 1048576 MCK cycles between 2 data transfers.
 #define DTOR_1MEGA_CYCLES           (AT91C_MCI_DTOCYC | AT91C_MCI_DTOMUL)

 /// MCI MR: disable MCI Clock when FIFO is full
 #ifndef AT91C_MCI_WRPROOF
     #define AT91C_MCI_WRPROOF 0
 #endif
 #ifndef AT91C_MCI_RDPROOF
     #define AT91C_MCI_RDPROOF 0
 #endif

 #define SDCARD_APP_OP_COND_CMD      (41 | AT91C_MCI_SPCMD_NONE  | AT91C_MCI_RSPTYP_48   | AT91C_MCI_TRCMD_NO )
 #define MMC_SEND_OP_COND_CMD        (1  | AT91C_MCI_TRCMD_NO    | AT91C_MCI_SPCMD_NONE  | AT91C_MCI_RSPTYP_48 | AT91C_MCI_OPDCMD)


 #define DISABLE    0    // Disable MCI interface
 #define ENABLE     1    // Enable MCI interface


 //------------------------------------------------------------------------------
 //         Local macros
 //------------------------------------------------------------------------------

 /// Used to write in PMC registers.
 #define WRITE_PMC(pPmc, regName, value)     pPmc->regName = (value)

 /// Used to write in MCI registers.
 #define WRITE_MCI(pMci, regName, value)     pMci->regName = (value)

 /// Used to read from MCI registers.
 #define READ_MCI(pMci, regName)             (pMci->regName)

 //------------------------------------------------------------------------------
 //         Global functions
 //------------------------------------------------------------------------------

 //------------------------------------------------------------------------------
 /// Enable/disable a MCI driver instance.
 /// \param pMci  Pointer to a MCI driver instance.
 /// \param enb  0 for disable MCI and 1 for enable MCI.
 //------------------------------------------------------------------------------
 void MCI_Enable(Mci *pMci, unsigned char enb)
 {
     AT91S_MCI *pMciHw = pMci->pMciHw;

     SANITY_CHECK(pMci);
     SANITY_CHECK(pMci->pMciHw);

     // Set the Control Register: Enable/Disable MCI interface clock
     if(enb == DISABLE) {
         WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIDIS);
     }
     else {
         WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIEN);
     }
 }

 //------------------------------------------------------------------------------
 /// Initializes a MCI driver instance and the underlying peripheral.
 /// \param pMci  Pointer to a MCI driver instance.
 /// \param pMciHw  Pointer to a MCI peripheral.
 /// \param mciId  MCI peripheral identifier.
 /// \param mode  Slot and type of connected card.
 //------------------------------------------------------------------------------
 void MCI_Init(
     Mci *pMci,
     AT91S_MCI *pMciHw,
     unsigned char mciId,
     unsigned int mode)
 {
     unsigned short clkDiv;

     SANITY_CHECK(pMci);
     SANITY_CHECK(pMciHw);
     SANITY_CHECK((mode == MCI_MMC_SLOTA) || (mode == MCI_MMC_SLOTB)
                  || (mode == MCI_SD_SLOTA) || (mode == MCI_SD_SLOTB));

     // Initialize the MCI driver structure
     pMci->pMciHw = pMciHw;
     pMci->mciId  = mciId;
     pMci->semaphore = 1;
     pMci->pCommand = 0;

     // Enable the MCI clock
     WRITE_PMC(AT91C_BASE_PMC, PMC_PCER, (1 << mciId));

      // Reset the MCI
     WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_SWRST);

     // Disable the MCI
     WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIDIS | AT91C_MCI_PWSDIS);

     // Disable all the interrupts
     WRITE_MCI(pMciHw, MCI_IDR, 0xFFFFFFFF);

     // Set the Data Timeout Register
     WRITE_MCI(pMciHw, MCI_DTOR, DTOR_1MEGA_CYCLES);

     // Set the Mode Register: 400KHz for MCK = 48MHz (CLKDIV = 58)
     clkDiv = (BOARD_MCK / (400000 * 2)) - 1;
     WRITE_MCI(pMciHw, MCI_MR, (clkDiv | (AT91C_MCI_PWSDIV & (0x7 << 8))));

     // Set the SDCard Register
     WRITE_MCI(pMciHw, MCI_SDCR, mode);

     // Enable the MCI and the Power Saving
     WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIEN);

     // Disable the MCI peripheral clock.
     WRITE_PMC(AT91C_BASE_PMC, PMC_PCDR, (1 << mciId));
 }

 //------------------------------------------------------------------------------
 /// Close a MCI driver instance and the underlying peripheral.
 /// \param pMci  Pointer to a MCI driver instance.
 /// \param pMciHw  Pointer to a MCI peripheral.
 /// \param mciId  MCI peripheral identifier.
 //------------------------------------------------------------------------------
 void MCI_Close(Mci *pMci)
 {
     AT91S_MCI *pMciHw = pMci->pMciHw;

     SANITY_CHECK(pMci);
     SANITY_CHECK(pMciHw);

     // Initialize the MCI driver structure
     pMci->semaphore = 1;
     pMci->pCommand = 0;

     // Disable the MCI peripheral clock.
     WRITE_PMC(AT91C_BASE_PMC, PMC_PCDR, (1 << pMci->mciId));

     // Disable the MCI
     WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIDIS);

     // Disable all the interrupts
     WRITE_MCI(pMciHw, MCI_IDR, 0xFFFFFFFF);
 }

 //------------------------------------------------------------------------------
 /// Configure the  MCI CLKDIV in the MCI_MR register. The max. for MCI clock is
 /// MCK/2 and corresponds to CLKDIV = 0
 /// \param pMci  Pointer to the low level MCI driver.
 /// \param mciSpeed  MCI clock speed in Hz.
 //------------------------------------------------------------------------------
 void MCI_SetSpeed(Mci *pMci, unsigned int mciSpeed)
 {
     AT91S_MCI *pMciHw = pMci->pMciHw;
     unsigned int mciMr;
     unsigned int clkdiv;

     SANITY_CHECK(pMci);
     SANITY_CHECK(pMci->pMciHw);

     // Set the Mode Register: 400KHz for MCK = 48MHz (CLKDIV = 58)
     mciMr = READ_MCI(pMciHw, MCI_MR) & (~AT91C_MCI_CLKDIV);

     // Multimedia Card Interface clock (MCCK or MCI_CK) is Master Clock (MCK)
     // divided by (2*(CLKDIV+1))
     if (mciSpeed > 0) {

         clkdiv = (BOARD_MCK / (mciSpeed * 2));
         if (clkdiv > 0) {

             clkdiv -= 1;
         }
         ASSERT( (clkdiv & 0xFFFFFF00) == 0, "mciSpeed too small");
     }
     else {

         clkdiv = 0;
     }

     WRITE_MCI(pMciHw, MCI_MR, mciMr | clkdiv);
 }

 //------------------------------------------------------------------------------
 /// Configure the  MCI SDCBUS in the MCI_SDCR register. Only two modes available
 ///
 /// \param pMci  Pointer to the low level MCI driver.
 /// \param busWidth  MCI bus width mode.
 //------------------------------------------------------------------------------
 void MCI_SetBusWidth(Mci *pMci, unsigned char busWidth)
 {
     AT91S_MCI *pMciHw = pMci->pMciHw;
     unsigned int mciSdcr;

     SANITY_CHECK(pMci);
     SANITY_CHECK(pMci->pMciHw);

     mciSdcr = (READ_MCI(pMciHw, MCI_SDCR) & ~(AT91C_MCI_SCDBUS));

     WRITE_MCI(pMciHw, MCI_SDCR, mciSdcr | busWidth);
 }

 //------------------------------------------------------------------------------
 /// Starts a MCI  transfer. This is a non blocking function. It will return
 /// as soon as the transfer is started.
 /// Return 0 if successful; otherwise returns MCI_ERROR_LOCK if the driver is
 /// already in use.
 /// \param pMci  Pointer to an MCI driver instance.
 /// \param pCommand  Pointer to the command to execute.
 //------------------------------------------------------------------------------
 unsigned char MCI_SendCommand(Mci *pMci, MciCmd *pCommand)
 {
     AT91PS_MCI pMciHw = pMci->pMciHw;
     unsigned int mciIer, mciMr;

     SANITY_CHECK(pMci);
     SANITY_CHECK(pMciHw);
     SANITY_CHECK(pCommand);

     // Try to acquire the MCI semaphore
     if (pMci->semaphore == 0) {

         return MCI_ERROR_LOCK;
     }
     pMci->semaphore--;
     // TRACE_DEBUG("MCI_SendCommand %x %d\n\r", READ_MCI(pMciHw, MCI_SR), pCommand->cmd & 0x3f);

     // Command is now being executed
     pMci->pCommand = pCommand;
     pCommand->status = MCI_STATUS_PENDING;

     // Enable the MCI clock
     WRITE_PMC(AT91C_BASE_PMC, PMC_PCER, (1 << pMci->mciId));

     //Disable MCI clock, for multi-block data transfer
     MCI_Enable(pMci, DISABLE);

     // Set PDC data transfer direction
     if(pCommand->blockSize > 0) {
         if(pCommand->isRead) {
             WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_RXTEN);
         }
         else {
             WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_TXTEN);
         }
     }
     // Disable transmitter and receiver
     WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_RXTDIS | AT91C_PDC_TXTDIS);

     mciMr = READ_MCI(pMciHw, MCI_MR) & (~(AT91C_MCI_WRPROOF|AT91C_MCI_RDPROOF|AT91C_MCI_BLKLEN | AT91C_MCI_PDCMODE));

     // Command with DATA stage
     if (pCommand->blockSize > 0) {
         // Enable PDC mode and set block size
         if(pCommand->conTrans != MCI_CONTINUE_TRANSFER) {

             WRITE_MCI(pMciHw, MCI_MR, mciMr | AT91C_MCI_PDCMODE |AT91C_MCI_RDPROOF|AT91C_MCI_WRPROOF|(pCommand->blockSize << 16));
         }

         // DATA transfer from card to host
         if (pCommand->isRead) {
             WRITE_MCI(pMciHw, MCI_RPR, (int) pCommand->pData);

             // Sanity check
             if (pCommand->nbBlock == 0)
                 pCommand->nbBlock = 1;
             ////////
             if ((pCommand->blockSize & 0x3) != 0) {
                 WRITE_MCI(pMciHw, MCI_RCR, (pCommand->nbBlock * pCommand->blockSize) / 4 + 1);
             }
             else {
                 WRITE_MCI(pMciHw, MCI_RCR, (pCommand->nbBlock * pCommand->blockSize) / 4);
             }

             WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_RXTEN);
             mciIer = AT91C_MCI_ENDRX | STATUS_ERRORS;
             // mciIer = AT91C_MCI_RXBUFF | STATUS_ERRORS;
         }

         // DATA transfer from host to card
         else {
             // Sanity check
             if (pCommand->nbBlock == 0)
                 pCommand->nbBlock = 1;
             WRITE_MCI(pMciHw, MCI_TPR, (int) pCommand->pData);
             // Update the PDC counter
             if ((pCommand->blockSize & 0x3) != 0) {
                 WRITE_MCI(pMciHw, MCI_TCR, (pCommand->nbBlock * pCommand->blockSize) / 4 + 1);
             }
             else {
                 WRITE_MCI(pMciHw, MCI_TCR, (pCommand->nbBlock * pCommand->blockSize) / 4);
             }
             // MCI_BLKE notifies the end of Multiblock command
             mciIer = AT91C_MCI_BLKE | STATUS_ERRORS;
         }
     }
     // No data transfer: stop at the end of the command
     else {
         WRITE_MCI(pMciHw, MCI_MR, mciMr);
         mciIer = AT91C_MCI_CMDRDY | STATUS_ERRORS;
     }
     // Enable MCI clock
     MCI_Enable(pMci, ENABLE);

     // Send the command
     if((pCommand->conTrans != MCI_CONTINUE_TRANSFER)
         || (pCommand->blockSize == 0)) {

         WRITE_MCI(pMciHw, MCI_ARGR, pCommand->arg);
         WRITE_MCI(pMciHw, MCI_CMDR, pCommand->cmd);
     }

     // In case of transmit, the PDC shall be enabled after sending the command
     if ((pCommand->blockSize > 0) && !(pCommand->isRead)) {
         WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_TXTEN);
     }

     // Ignore data error
     mciIer &= ~(AT91C_MCI_UNRE | AT91C_MCI_OVRE \
               | AT91C_MCI_DTOE | AT91C_MCI_DCRCE);

     // Interrupt enable shall be done after PDC TXTEN and RXTEN
     WRITE_MCI(pMciHw, MCI_IER, mciIer);

     return 0;
 }

 //------------------------------------------------------------------------------
 /// Check NOTBUSY and DTIP bits of status register on the given MCI driver.
 /// Return value, 0 for bus ready, 1 for bus busy
 /// \param pMci  Pointer to a MCI driver instance.
 //------------------------------------------------------------------------------
 unsigned char MCI_CheckBusy(Mci *pMci)
 {
     AT91S_MCI *pMciHw = pMci->pMciHw;
     unsigned int status;

     // Enable MCI clock
     MCI_Enable(pMci, ENABLE);

     status = READ_MCI(pMciHw, MCI_SR);
     // TRACE_DEBUG("status %x\n\r",status);


     if(((status & AT91C_MCI_NOTBUSY)!=0)
         && ((status & AT91C_MCI_DTIP)==0)) {

         // Disable MCI clock
         MCI_Enable(pMci, DISABLE);

         return 0;
     }
     else {
         return 1;
     }
 }

 //------------------------------------------------------------------------------
 /// Check BLKE bit of status register on the given MCI driver.
 /// \param pMci  Pointer to a MCI driver instance.
 //------------------------------------------------------------------------------
 unsigned char MCI_CheckBlke(Mci *pMci)
 {
     AT91S_MCI *pMciHw = pMci->pMciHw;
     unsigned int status;

     status = READ_MCI(pMciHw, MCI_SR);
     // TRACE_DEBUG("status %x\n\r",status);

     if((status & AT91C_MCI_BLKE)!=0) {
         return 0;
     }
     else {
         return 1;
     }
 }

 //------------------------------------------------------------------------------
 /// Processes pending events on the given MCI driver.
 /// \param pMci  Pointer to a MCI driver instance.
 //------------------------------------------------------------------------------
 void MCI_Handler(Mci *pMci)
 {
     AT91S_MCI *pMciHw = pMci->pMciHw;
     MciCmd *pCommand = pMci->pCommand;
     unsigned int status;
     unsigned char i;
     #if defined(at91rm9200)
     unsigned int mciCr, mciSdcr, mciMr, mciDtor;
     #endif

     SANITY_CHECK(pMci);
     SANITY_CHECK(pMciHw);
     SANITY_CHECK(pCommand);

     // Read the status register
     status = READ_MCI(pMciHw, MCI_SR) & READ_MCI(pMciHw, MCI_IMR);
     // TRACE_DEBUG("status %x\n\r", status);

     // Check if an error has occured
     if ((status & STATUS_ERRORS) != 0) {

         // Check error code
         if ((status & STATUS_ERRORS) == AT91C_MCI_RTOE) {

             pCommand->status = MCI_STATUS_NORESPONSE;
         }
         // if the command is SEND_OP_COND the CRC error flag is always present
         // (cf : R3 response)
         else if (((status & STATUS_ERRORS) != AT91C_MCI_RCRCE)
                   || ((pCommand->cmd != SDCARD_APP_OP_COND_CMD)
                       && (pCommand->cmd != MMC_SEND_OP_COND_CMD))) {

             pCommand->status = MCI_STATUS_ERROR;
         }
     }

     // Check if a transfer has been completed
     if (((status & AT91C_MCI_CMDRDY) != 0)
         || ((status & AT91C_MCI_ENDRX) != 0)
         || ((status & AT91C_MCI_RXBUFF) != 0)
         || ((status & AT91C_MCI_ENDTX) != 0)
         || ((status & AT91C_MCI_BLKE) != 0)
         || ((status & AT91C_MCI_RTOE) != 0)) {

         if (((status & AT91C_MCI_ENDRX) != 0)
             || ((status & AT91C_MCI_RXBUFF) != 0)
             || ((status & AT91C_MCI_ENDTX) != 0)) {

             MCI_Enable(pMci, DISABLE);
         }

         /// On AT91RM9200-EK, if stop transmission, software reset MCI.
         #if defined(at91rm9200)
         if ((pCommand->cmd & AT91C_MCI_TRCMD_STOP) != 0) {
             mciMr = READ_MCI(pMciHw, MCI_MR);
             mciSdcr = READ_MCI(pMciHw, MCI_SDCR);
             mciDtor = READ_MCI(pMciHw, MCI_DTOR);
             WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_SWRST);
             // TRACE_DEBUG("reset MCI\n\r");

             WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIDIS | AT91C_MCI_PWSDIS);
             WRITE_MCI(pMciHw, MCI_MR, mciMr);
             WRITE_MCI(pMciHw, MCI_SDCR, mciSdcr);
             WRITE_MCI(pMciHw, MCI_DTOR, mciDtor);
         }
         #endif

         // If no error occured, the transfer is successful
         if (pCommand->status == MCI_STATUS_PENDING) {
             pCommand->status = 0;
         }
 #if 0
         if ((status & AT91C_MCI_CMDRDY) != 0)
             TRACE_DEBUG_WP(".");
         if ((status & AT91C_MCI_ENDRX) != 0)
             TRACE_DEBUG_WP("<");
         if ((status & AT91C_MCI_ENDTX) != 0)
             TRACE_DEBUG_WP("-");
         if ((status & AT91C_MCI_BLKE) != 0)
             TRACE_DEBUG_WP(">");
         TRACE_DEBUG_WP("\n\r");
 #endif
         // Store the card response in the provided buffer
         if (pCommand->pResp) {
             unsigned char resSize;

             switch (pCommand->resType) {
                 case 1:
                 resSize = 1;
                 break;

                 case 2:
                 resSize = 4;
                 break;

                 case 3:
                 resSize = 1;
                 break;

                 case 4:
                 resSize = 1;
                 break;

                 case 5:
                 resSize = 1;
                 break;

                 case 6:
                 resSize = 1;
                 break;

                 case 7:
                 resSize = 1;
                 break;

                 default:
                 resSize = 0;
                 break;
             }
             for (i=0; i < resSize; i++) {

                 pCommand->pResp[i] = READ_MCI(pMciHw, MCI_RSPR[0]);
             }
         }

         // Disable interrupts
         WRITE_MCI(pMciHw, MCI_IDR, READ_MCI(pMciHw, MCI_IMR));

         // Release the semaphore
         pMci->semaphore++;

         // Invoke the callback associated with the current command (if any)
         if (pCommand->callback) {
             (pCommand->callback)(pCommand->status, pCommand);
         }
     }
 }

 //------------------------------------------------------------------------------
 /// Returns 1 if the given MCI transfer is complete; otherwise returns 0.
 /// \param pCommand  Pointer to a MciCmd instance.
 //------------------------------------------------------------------------------
 unsigned char MCI_IsTxComplete(MciCmd *pCommand)
 {
     if (pCommand->status != MCI_STATUS_PENDING) {
         if (pCommand->status != 0) {
             TRACE_DEBUG("MCI_IsTxComplete %d\n\r", pCommand->status);
         }
         return 1;
     }
     else {
         return 0;
     }
 }
	/* ----------------------------------------------------------------------------
	* ATMEL Microcontroller Software Support
	* ----------------------------------------------------------------------------
	* Copyright (c) 2008, 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.
	* ----------------------------------------------------------------------------
	*/

	//------------------------------------------------------------------------------
	// Headers
	//------------------------------------------------------------------------------

	#include "mci.h"
	#include <utility/assert.h>
	#include <utility/trace.h>

	//------------------------------------------------------------------------------
	// Local constants
	//------------------------------------------------------------------------------

	/// Bit mask for status register errors.
	#define STATUS_ERRORS (AT91C_MCI_UNRE \
	\| AT91C_MCI_OVRE \
	\| AT91C_MCI_DTOE \
	\| AT91C_MCI_DCRCE \
	\| AT91C_MCI_RTOE \
	\| AT91C_MCI_RENDE \
	\| AT91C_MCI_RCRCE \
	\| AT91C_MCI_RDIRE \
	\| AT91C_MCI_RINDE)

	/// MCI data timeout configuration with 1048576 MCK cycles between 2 data transfers.
	#define DTOR_1MEGA_CYCLES (AT91C_MCI_DTOCYC \| AT91C_MCI_DTOMUL)

	/// MCI MR: disable MCI Clock when FIFO is full
	#ifndef AT91C_MCI_WRPROOF
	#define AT91C_MCI_WRPROOF 0
	#endif
	#ifndef AT91C_MCI_RDPROOF
	#define AT91C_MCI_RDPROOF 0
	#endif

	#define SDCARD_APP_OP_COND_CMD (41 \| AT91C_MCI_SPCMD_NONE \| AT91C_MCI_RSPTYP_48 \| AT91C_MCI_TRCMD_NO )
	#define MMC_SEND_OP_COND_CMD (1 \| AT91C_MCI_TRCMD_NO \| AT91C_MCI_SPCMD_NONE \| AT91C_MCI_RSPTYP_48 \| AT91C_MCI_OPDCMD)


	#define DISABLE 0 // Disable MCI interface
	#define ENABLE 1 // Enable MCI interface


	//------------------------------------------------------------------------------
	// Local macros
	//------------------------------------------------------------------------------

	/// Used to write in PMC registers.
	#define WRITE_PMC(pPmc, regName, value) pPmc->regName = (value)

	/// Used to write in MCI registers.
	#define WRITE_MCI(pMci, regName, value) pMci->regName = (value)

	/// Used to read from MCI registers.
	#define READ_MCI(pMci, regName) (pMci->regName)

	//------------------------------------------------------------------------------
	// Global functions
	//------------------------------------------------------------------------------

	//------------------------------------------------------------------------------
	/// Enable/disable a MCI driver instance.
	/// \param pMci Pointer to a MCI driver instance.
	/// \param enb 0 for disable MCI and 1 for enable MCI.
	//------------------------------------------------------------------------------
	void MCI_Enable(Mci *pMci, unsigned char enb)
	{
	AT91S_MCI *pMciHw = pMci->pMciHw;

	SANITY_CHECK(pMci);
	SANITY_CHECK(pMci->pMciHw);

	// Set the Control Register: Enable/Disable MCI interface clock
	if(enb == DISABLE) {
	WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIDIS);
	}
	else {
	WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIEN);
	}
	}

	//------------------------------------------------------------------------------
	/// Initializes a MCI driver instance and the underlying peripheral.
	/// \param pMci Pointer to a MCI driver instance.
	/// \param pMciHw Pointer to a MCI peripheral.
	/// \param mciId MCI peripheral identifier.
	/// \param mode Slot and type of connected card.
	//------------------------------------------------------------------------------
	void MCI_Init(
	Mci *pMci,
	AT91S_MCI *pMciHw,
	unsigned char mciId,
	unsigned int mode)
	{
	unsigned short clkDiv;

	SANITY_CHECK(pMci);
	SANITY_CHECK(pMciHw);
	SANITY_CHECK((mode == MCI_MMC_SLOTA) \|\| (mode == MCI_MMC_SLOTB)
	\|\| (mode == MCI_SD_SLOTA) \|\| (mode == MCI_SD_SLOTB));

	// Initialize the MCI driver structure
	pMci->pMciHw = pMciHw;
	pMci->mciId = mciId;
	pMci->semaphore = 1;
	pMci->pCommand = 0;

	// Enable the MCI clock
	WRITE_PMC(AT91C_BASE_PMC, PMC_PCER, (1 << mciId));

	// Reset the MCI
	WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_SWRST);

	// Disable the MCI
	WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIDIS \| AT91C_MCI_PWSDIS);

	// Disable all the interrupts
	WRITE_MCI(pMciHw, MCI_IDR, 0xFFFFFFFF);

	// Set the Data Timeout Register
	WRITE_MCI(pMciHw, MCI_DTOR, DTOR_1MEGA_CYCLES);

	// Set the Mode Register: 400KHz for MCK = 48MHz (CLKDIV = 58)
	clkDiv = (BOARD_MCK / (400000 * 2)) - 1;
	WRITE_MCI(pMciHw, MCI_MR, (clkDiv \| (AT91C_MCI_PWSDIV & (0x7 << 8))));

	// Set the SDCard Register
	WRITE_MCI(pMciHw, MCI_SDCR, mode);

	// Enable the MCI and the Power Saving
	WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIEN);

	// Disable the MCI peripheral clock.
	WRITE_PMC(AT91C_BASE_PMC, PMC_PCDR, (1 << mciId));
	}

	//------------------------------------------------------------------------------
	/// Close a MCI driver instance and the underlying peripheral.
	/// \param pMci Pointer to a MCI driver instance.
	/// \param pMciHw Pointer to a MCI peripheral.
	/// \param mciId MCI peripheral identifier.
	//------------------------------------------------------------------------------
	void MCI_Close(Mci *pMci)
	{
	AT91S_MCI *pMciHw = pMci->pMciHw;

	SANITY_CHECK(pMci);
	SANITY_CHECK(pMciHw);

	// Initialize the MCI driver structure
	pMci->semaphore = 1;
	pMci->pCommand = 0;

	// Disable the MCI peripheral clock.
	WRITE_PMC(AT91C_BASE_PMC, PMC_PCDR, (1 << pMci->mciId));

	// Disable the MCI
	WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIDIS);

	// Disable all the interrupts
	WRITE_MCI(pMciHw, MCI_IDR, 0xFFFFFFFF);
	}

	//------------------------------------------------------------------------------
	/// Configure the MCI CLKDIV in the MCI_MR register. The max. for MCI clock is
	/// MCK/2 and corresponds to CLKDIV = 0
	/// \param pMci Pointer to the low level MCI driver.
	/// \param mciSpeed MCI clock speed in Hz.
	//------------------------------------------------------------------------------
	void MCI_SetSpeed(Mci *pMci, unsigned int mciSpeed)
	{
	AT91S_MCI *pMciHw = pMci->pMciHw;
	unsigned int mciMr;
	unsigned int clkdiv;

	SANITY_CHECK(pMci);
	SANITY_CHECK(pMci->pMciHw);

	// Set the Mode Register: 400KHz for MCK = 48MHz (CLKDIV = 58)
	mciMr = READ_MCI(pMciHw, MCI_MR) & (~AT91C_MCI_CLKDIV);

	// Multimedia Card Interface clock (MCCK or MCI_CK) is Master Clock (MCK)
	// divided by (2*(CLKDIV+1))
	if (mciSpeed > 0) {

	clkdiv = (BOARD_MCK / (mciSpeed * 2));
	if (clkdiv > 0) {

	clkdiv -= 1;
	}
	ASSERT( (clkdiv & 0xFFFFFF00) == 0, "mciSpeed too small");
	}
	else {

	clkdiv = 0;
	}

	WRITE_MCI(pMciHw, MCI_MR, mciMr \| clkdiv);
	}

	//------------------------------------------------------------------------------
	/// Configure the MCI SDCBUS in the MCI_SDCR register. Only two modes available
	///
	/// \param pMci Pointer to the low level MCI driver.
	/// \param busWidth MCI bus width mode.
	//------------------------------------------------------------------------------
	void MCI_SetBusWidth(Mci *pMci, unsigned char busWidth)
	{
	AT91S_MCI *pMciHw = pMci->pMciHw;
	unsigned int mciSdcr;

	SANITY_CHECK(pMci);
	SANITY_CHECK(pMci->pMciHw);

	mciSdcr = (READ_MCI(pMciHw, MCI_SDCR) & ~(AT91C_MCI_SCDBUS));

	WRITE_MCI(pMciHw, MCI_SDCR, mciSdcr \| busWidth);
	}

	//------------------------------------------------------------------------------
	/// Starts a MCI transfer. This is a non blocking function. It will return
	/// as soon as the transfer is started.
	/// Return 0 if successful; otherwise returns MCI_ERROR_LOCK if the driver is
	/// already in use.
	/// \param pMci Pointer to an MCI driver instance.
	/// \param pCommand Pointer to the command to execute.
	//------------------------------------------------------------------------------
	unsigned char MCI_SendCommand(Mci pMci, MciCmd pCommand)
	{
	AT91PS_MCI pMciHw = pMci->pMciHw;
	unsigned int mciIer, mciMr;

	SANITY_CHECK(pMci);
	SANITY_CHECK(pMciHw);
	SANITY_CHECK(pCommand);

	// Try to acquire the MCI semaphore
	if (pMci->semaphore == 0) {

	return MCI_ERROR_LOCK;
	}
	pMci->semaphore--;
	// TRACE_DEBUG("MCI_SendCommand %x %d\n\r", READ_MCI(pMciHw, MCI_SR), pCommand->cmd & 0x3f);

	// Command is now being executed
	pMci->pCommand = pCommand;
	pCommand->status = MCI_STATUS_PENDING;

	// Enable the MCI clock
	WRITE_PMC(AT91C_BASE_PMC, PMC_PCER, (1 << pMci->mciId));

	//Disable MCI clock, for multi-block data transfer
	MCI_Enable(pMci, DISABLE);

	// Set PDC data transfer direction
	if(pCommand->blockSize > 0) {
	if(pCommand->isRead) {
	WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_RXTEN);
	}
	else {
	WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_TXTEN);
	}
	}
	// Disable transmitter and receiver
	WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_RXTDIS \| AT91C_PDC_TXTDIS);

	mciMr = READ_MCI(pMciHw, MCI_MR) & (~(AT91C_MCI_WRPROOF\|AT91C_MCI_RDPROOF\|AT91C_MCI_BLKLEN \| AT91C_MCI_PDCMODE));

	// Command with DATA stage
	if (pCommand->blockSize > 0) {
	// Enable PDC mode and set block size
	if(pCommand->conTrans != MCI_CONTINUE_TRANSFER) {

	WRITE_MCI(pMciHw, MCI_MR, mciMr \| AT91C_MCI_PDCMODE \|AT91C_MCI_RDPROOF\|AT91C_MCI_WRPROOF\|(pCommand->blockSize << 16));
	}

	// DATA transfer from card to host
	if (pCommand->isRead) {
	WRITE_MCI(pMciHw, MCI_RPR, (int) pCommand->pData);

	// Sanity check
	if (pCommand->nbBlock == 0)
	pCommand->nbBlock = 1;
	////////
	if ((pCommand->blockSize & 0x3) != 0) {
	WRITE_MCI(pMciHw, MCI_RCR, (pCommand->nbBlock * pCommand->blockSize) / 4 + 1);
	}
	else {
	WRITE_MCI(pMciHw, MCI_RCR, (pCommand->nbBlock * pCommand->blockSize) / 4);
	}

	WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_RXTEN);
	mciIer = AT91C_MCI_ENDRX \| STATUS_ERRORS;
	// mciIer = AT91C_MCI_RXBUFF \| STATUS_ERRORS;
	}

	// DATA transfer from host to card
	else {
	// Sanity check
	if (pCommand->nbBlock == 0)
	pCommand->nbBlock = 1;
	WRITE_MCI(pMciHw, MCI_TPR, (int) pCommand->pData);
	// Update the PDC counter
	if ((pCommand->blockSize & 0x3) != 0) {
	WRITE_MCI(pMciHw, MCI_TCR, (pCommand->nbBlock * pCommand->blockSize) / 4 + 1);
	}
	else {
	WRITE_MCI(pMciHw, MCI_TCR, (pCommand->nbBlock * pCommand->blockSize) / 4);
	}
	// MCI_BLKE notifies the end of Multiblock command
	mciIer = AT91C_MCI_BLKE \| STATUS_ERRORS;
	}
	}
	// No data transfer: stop at the end of the command
	else {
	WRITE_MCI(pMciHw, MCI_MR, mciMr);
	mciIer = AT91C_MCI_CMDRDY \| STATUS_ERRORS;
	}
	// Enable MCI clock
	MCI_Enable(pMci, ENABLE);

	// Send the command
	if((pCommand->conTrans != MCI_CONTINUE_TRANSFER)
	\|\| (pCommand->blockSize == 0)) {

	WRITE_MCI(pMciHw, MCI_ARGR, pCommand->arg);
	WRITE_MCI(pMciHw, MCI_CMDR, pCommand->cmd);
	}

	// In case of transmit, the PDC shall be enabled after sending the command
	if ((pCommand->blockSize > 0) && !(pCommand->isRead)) {
	WRITE_MCI(pMciHw, MCI_PTCR, AT91C_PDC_TXTEN);
	}

	// Ignore data error
	mciIer &= ~(AT91C_MCI_UNRE \| AT91C_MCI_OVRE \
	\| AT91C_MCI_DTOE \| AT91C_MCI_DCRCE);

	// Interrupt enable shall be done after PDC TXTEN and RXTEN
	WRITE_MCI(pMciHw, MCI_IER, mciIer);

	return 0;
	}

	//------------------------------------------------------------------------------
	/// Check NOTBUSY and DTIP bits of status register on the given MCI driver.
	/// Return value, 0 for bus ready, 1 for bus busy
	/// \param pMci Pointer to a MCI driver instance.
	//------------------------------------------------------------------------------
	unsigned char MCI_CheckBusy(Mci *pMci)
	{
	AT91S_MCI *pMciHw = pMci->pMciHw;
	unsigned int status;

	// Enable MCI clock
	MCI_Enable(pMci, ENABLE);

	status = READ_MCI(pMciHw, MCI_SR);
	// TRACE_DEBUG("status %x\n\r",status);


	if(((status & AT91C_MCI_NOTBUSY)!=0)
	&& ((status & AT91C_MCI_DTIP)==0)) {

	// Disable MCI clock
	MCI_Enable(pMci, DISABLE);

	return 0;
	}
	else {
	return 1;
	}
	}

	//------------------------------------------------------------------------------
	/// Check BLKE bit of status register on the given MCI driver.
	/// \param pMci Pointer to a MCI driver instance.
	//------------------------------------------------------------------------------
	unsigned char MCI_CheckBlke(Mci *pMci)
	{
	AT91S_MCI *pMciHw = pMci->pMciHw;
	unsigned int status;

	status = READ_MCI(pMciHw, MCI_SR);
	// TRACE_DEBUG("status %x\n\r",status);

	if((status & AT91C_MCI_BLKE)!=0) {
	return 0;
	}
	else {
	return 1;
	}
	}

	//------------------------------------------------------------------------------
	/// Processes pending events on the given MCI driver.
	/// \param pMci Pointer to a MCI driver instance.
	//------------------------------------------------------------------------------
	void MCI_Handler(Mci *pMci)
	{
	AT91S_MCI *pMciHw = pMci->pMciHw;
	MciCmd *pCommand = pMci->pCommand;
	unsigned int status;
	unsigned char i;
	#if defined(at91rm9200)
	unsigned int mciCr, mciSdcr, mciMr, mciDtor;
	#endif

	SANITY_CHECK(pMci);
	SANITY_CHECK(pMciHw);
	SANITY_CHECK(pCommand);

	// Read the status register
	status = READ_MCI(pMciHw, MCI_SR) & READ_MCI(pMciHw, MCI_IMR);
	// TRACE_DEBUG("status %x\n\r", status);

	// Check if an error has occured
	if ((status & STATUS_ERRORS) != 0) {

	// Check error code
	if ((status & STATUS_ERRORS) == AT91C_MCI_RTOE) {

	pCommand->status = MCI_STATUS_NORESPONSE;
	}
	// if the command is SEND_OP_COND the CRC error flag is always present
	// (cf : R3 response)
	else if (((status & STATUS_ERRORS) != AT91C_MCI_RCRCE)
	\|\| ((pCommand->cmd != SDCARD_APP_OP_COND_CMD)
	&& (pCommand->cmd != MMC_SEND_OP_COND_CMD))) {

	pCommand->status = MCI_STATUS_ERROR;
	}
	}

	// Check if a transfer has been completed
	if (((status & AT91C_MCI_CMDRDY) != 0)
	\|\| ((status & AT91C_MCI_ENDRX) != 0)
	\|\| ((status & AT91C_MCI_RXBUFF) != 0)
	\|\| ((status & AT91C_MCI_ENDTX) != 0)
	\|\| ((status & AT91C_MCI_BLKE) != 0)
	\|\| ((status & AT91C_MCI_RTOE) != 0)) {

	if (((status & AT91C_MCI_ENDRX) != 0)
	\|\| ((status & AT91C_MCI_RXBUFF) != 0)
	\|\| ((status & AT91C_MCI_ENDTX) != 0)) {

	MCI_Enable(pMci, DISABLE);
	}

	/// On AT91RM9200-EK, if stop transmission, software reset MCI.
	#if defined(at91rm9200)
	if ((pCommand->cmd & AT91C_MCI_TRCMD_STOP) != 0) {
	mciMr = READ_MCI(pMciHw, MCI_MR);
	mciSdcr = READ_MCI(pMciHw, MCI_SDCR);
	mciDtor = READ_MCI(pMciHw, MCI_DTOR);
	WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_SWRST);
	// TRACE_DEBUG("reset MCI\n\r");

	WRITE_MCI(pMciHw, MCI_CR, AT91C_MCI_MCIDIS \| AT91C_MCI_PWSDIS);
	WRITE_MCI(pMciHw, MCI_MR, mciMr);
	WRITE_MCI(pMciHw, MCI_SDCR, mciSdcr);
	WRITE_MCI(pMciHw, MCI_DTOR, mciDtor);
	}
	#endif

	// If no error occured, the transfer is successful
	if (pCommand->status == MCI_STATUS_PENDING) {
	pCommand->status = 0;
	}
	#if 0
	if ((status & AT91C_MCI_CMDRDY) != 0)
	TRACE_DEBUG_WP(".");
	if ((status & AT91C_MCI_ENDRX) != 0)
	TRACE_DEBUG_WP("<");
	if ((status & AT91C_MCI_ENDTX) != 0)
	TRACE_DEBUG_WP("-");
	if ((status & AT91C_MCI_BLKE) != 0)
	TRACE_DEBUG_WP(">");
	TRACE_DEBUG_WP("\n\r");
	#endif
	// Store the card response in the provided buffer
	if (pCommand->pResp) {
	unsigned char resSize;

	switch (pCommand->resType) {
	case 1:
	resSize = 1;
	break;

	case 2:
	resSize = 4;
	break;

	case 3:
	resSize = 1;
	break;

	case 4:
	resSize = 1;
	break;

	case 5:
	resSize = 1;
	break;

	case 6:
	resSize = 1;
	break;

	case 7:
	resSize = 1;
	break;

	default:
	resSize = 0;
	break;
	}
	for (i=0; i < resSize; i++) {

	pCommand->pResp[i] = READ_MCI(pMciHw, MCI_RSPR[0]);
	}
	}

	// Disable interrupts
	WRITE_MCI(pMciHw, MCI_IDR, READ_MCI(pMciHw, MCI_IMR));

	// Release the semaphore
	pMci->semaphore++;

	// Invoke the callback associated with the current command (if any)
	if (pCommand->callback) {
	(pCommand->callback)(pCommand->status, pCommand);
	}
	}
	}

	//------------------------------------------------------------------------------
	/// Returns 1 if the given MCI transfer is complete; otherwise returns 0.
	/// \param pCommand Pointer to a MciCmd instance.
	//------------------------------------------------------------------------------
	unsigned char MCI_IsTxComplete(MciCmd *pCommand)
	{
	if (pCommand->status != MCI_STATUS_PENDING) {
	if (pCommand->status != 0) {
	TRACE_DEBUG("MCI_IsTxComplete %d\n\r", pCommand->status);
	}
	return 1;
	}
	else {
	return 0;
	}
	}