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TI MSP430 Rwsdmmc Mmc.c

//  ***********************************************************
// File: mmc.c 
// Description: Library to access a MultiMediaCard 
//              functions: init, read, write ...
//  C. Speck / S. Schauer
//  Texas Instruments, Inc
//  June 2005
//
// Version 1.1
//   corrected comments about connection the MMC to the MSP430
//   increased timeout in mmcGetXXResponse
//
// ***********************************************************
// MMC Lib
// ***********************************************************


/* ***********************************************************
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* INCLUDING ANY IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS 
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* TI DISCLAIMS ANY WARRANTY OF TITLE, QUIET ENJOYMENT, QUIET 
* POSSESSION, AND NON-INFRINGEMENT OF ANY THIRD PARTY 
* INTELLECTUAL PROPERTY RIGHTS WITH REGARD TO THE PROGRAM OR 
* YOUR USE OF THE PROGRAM.
*
* IN NO EVENT SHALL TI BE LIABLE FOR ANY SPECIAL, INCIDENTAL, 
* CONSEQUENTIAL OR INDIRECT DAMAGES, HOWEVER CAUSED, ON ANY 
* THEORY OF LIABILITY AND WHETHER OR NOT TI HAS BEEN ADVISED 
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* OF THIS AGREEMENT, THE PROGRAM, OR YOUR USE OF THE PROGRAM. 
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* (U.S.$500).
*
* Unless otherwise stated, the Program written and copyrighted 
* by Texas Instruments is distributed as "freeware".  You may, 
* only under TI's copyright in the Program, use and modify the 
* Program without any charge or restriction.  You may 
* distribute to third parties, provided that you transfer a 
* copy of this license to the third party and the third party 
* agrees to these terms by its first use of the Program. You 
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*
* You may not use the Program in non-TI devices.
* ********************************************************* */


// ********************************************************
//
//   
//
//            MSP430F169                  MMC Card 
//         -----------------          -----------------
//     /|\|              XIN|-   /|\ |                 |
//      | |                 |     |  |                 |
//      --|RST          XOUT|-    |--|Pin4/Vcc         |
//        |                 |        |                 |
//        |                 |        |                 |
//        |            P5.0 |<-------|Pin6/CD          |
//        |            P5.4 |------->|Pin1/CS          |
//        |                 |        |                 |
//        |      P5.2/SOMI1 |------->|Pin2/DIN         |
//        |      P5.1/SIMO1 |<-------|Pin7/DOUT        |
//        |      P5.3/UCLK1 |------->|Pin5/CLK         |
//        |                 |        |                 |
//        |                 |     |--|Pin3/GND         |
//                                |
//                                =
//
//  Pin configuration at MSP430F169:
//  --------------------------------
//  MSP430F169      MSP Pin        MMC             MMC Pin
//  -------------------------------------------------------------
//  P5.4              48           ChipSelect       1
//  P5.2 / SOMI       46           DataIn           2
//                                 GND              3 (0 V)
//                                 VDD              4 (3.3 V)
//  P5.3 / UCLK1      47           Clock            5
//  P5.0              44           CardDetect       6
//  P5.1 / SIMO       45           DataOut          7
//  -------------------------------------------------------------
//
//
//
//
#ifndef _MMCLIB_C
#define _MMCLIB_C
//
//---------------------------------------------------------------
#include "mmc.h"
#include  "MSP430x16x.H"

//#define withDMA


// Function Prototypes
char mmcGetResponse(void);
char mmcGetXXResponse(const char resp);
char mmcCheckBusy(void);
void initSPI (void);
unsigned char spiSendByte(const unsigned char data);
char mmc_GoIdle();

// Varialbes
char mmc_buffer[512] = { 0 };               // Buffer for mmc i/o for data and registers

//---------------------------------------------------------------------

// setup usart1 in spi mode
void initSPI (void)
{
  UCTL1 = SWRST;                            // 8-bit SPI Master **SWRST**
  UTCTL1 = CKPH | SSEL1 | SSEL0 | STC;      // SMCLK, 3-pin mode, clock idle low, data valid on rising edge, UCLK delayed
  UBR01 = 0x02;                             // 0x02: UCLK/2 (4 MHz), works also with 3 and 4
  UBR11 = 0x00;                             // -"-
  UMCTL1 = 0x00;                            // no modulation
  UCTL1 = CHAR | SYNC | MM | SWRST;         // 8-bit SPI Master **SWRST**
  UCTL1 &= ~SWRST;                          // clear SWRST
  ME2 |= USPIE1;                            // Enable USART1 SPI mode
  while (!(IFG2 & UTXIFG1));                // USART1 TX buffer ready (empty)?
}


// Initialize MMC card
char initMMC (void)
{

  //raise SS and MOSI for 80 clock cycles
  //SendByte(0xff) 10 times with SS high
  //RAISE SS
  int i;

  // Port 5 Function           Dir       On/Off
  //         5.0-mmcCD         Out       0 - card inserted
  //         5.1-Dout          Out       0 - off    1 - On -> init in SPI_Init
  //         5.2-Din           Inp       0 - off    1 - On -> init in SPI_Init
  //         5.3-Clk           Out       -                 -> init in SPI_Init
  //         5.4-mmcCS         Out       0 - Active 1 - none Active

  P5SEL |= 0x0E;
  P5SEL &= ~0x11;
  P5OUT |= 0x10;
  P5DIR |= 0x1A;

  initSPI();
  //initialization sequence on PowerUp
  CS_HIGH();
  for(i=0;i<=9;i++)
    spiSendByte(0xff);

  return (mmc_GoIdle());
}


char mmc_GoIdle()
{
  char response=0x01;
  CS_LOW();

  //Send Command 0 to put MMC in SPI mode
  mmcSendCmd(MMC_GO_IDLE_STATE,0,0x95);
  //Now wait for READY RESPONSE
  if(mmcGetResponse()!=0x01)
    return MMC_INIT_ERROR;

  while(response==0x01)
  {
    CS_HIGH();
    spiSendByte(0xff);
    CS_LOW();
    mmcSendCmd(MMC_SEND_OP_COND,0x00,0xff);
    response=mmcGetResponse();
  }
  CS_HIGH();
  spiSendByte(0xff);
  return (MMC_SUCCESS);
}

// mmc Get Responce
char mmcGetResponse(void)
{
  //Response comes 1-8bytes after command
  //the first bit will be a 0
  //followed by an error code
  //data will be 0xff until response
  int i=0;

  char response;

  while(i<=64)
  {
    response=spiSendByte(0xff);
    if(response==0x00)break;
    if(response==0x01)break;
    i++;
  }
  return response;
}

char mmcGetXXResponse(const char resp)
{
  //Response comes 1-8bytes after command
  //the first bit will be a 0
  //followed by an error code
  //data will be 0xff until response
  int i=0;

  char response;

  while(i<=1000)
  {
    response=spiSendByte(0xff);
    if(response==resp)break;
    i++;
  }
  return response;
}
char mmcCheckBusy(void)
{
  //Response comes 1-8bytes after command
  //the first bit will be a 0
  //followed by an error code
  //data will be 0xff until response
  int i=0;

  char response;
  char rvalue;
  while(i<=64)
  {
    response=spiSendByte(0xff);
    response &= 0x1f;
    switch(response)
    {
      case 0x05: rvalue=MMC_SUCCESS;break;
      case 0x0b: return(MMC_CRC_ERROR);
      case 0x0d: return(MMC_WRITE_ERROR);
      default:
        rvalue = MMC_OTHER_ERROR;
        break;
    }
    if(rvalue==MMC_SUCCESS)break;
    i++;
  }
  i=0;
  do
  {
    response=spiSendByte(0xff);
    i++;
  }while(response==0);
  return response;
}

// The card will respond with a standard response token followed by a data
// block suffixed with a 16 bit CRC.

char mmcReadBlock(const unsigned long address, const unsigned long count, unsigned char *pBuffer)
{
  unsigned long i = 0;
  char rvalue = MMC_RESPONSE_ERROR;

  // Set the block length to read
  if (mmcSetBlockLength (count) == MMC_SUCCESS)   // block length could be set
  {
    // SS = LOW (on)
    CS_LOW ();
    // send read command MMC_READ_SINGLE_BLOCK=CMD17
    mmcSendCmd (MMC_READ_SINGLE_BLOCK,address, 0xFF);
    // Send 8 Clock pulses of delay, check if the MMC acknowledged the read block command
    // it will do this by sending an affirmative response
    // in the R1 format (0x00 is no errors)
    if (mmcGetResponse() == 0x00)
    {
      // now look for the data token to signify the start of
      // the data
      if (mmcGetXXResponse(MMC_START_DATA_BLOCK_TOKEN) == MMC_START_DATA_BLOCK_TOKEN)
      {
#ifndef withDMA
        // clock the actual data transfer and receive the bytes; spi_read automatically finds the Data Block
        for (i = 0; i < count; i++)
          pBuffer[i] = spiSendByte(0xff);   // is executed with card inserted
#else
        U1IFG &= ~(URXIFG1 + URXIFG1);      /* clear flags */
        /* Get the block */
        /* DMA trigger is UART1 receive for both DMA0 and DMA1 */
        DMACTL0 &= ~(DMA0TSEL_15 | DMA1TSEL_15);
        DMACTL0 |= (DMA0TSEL_9 | DMA1TSEL_9);
        /* Source DMA address: receive register.  */
        DMA0SA = U1RXBUF_;
        /* Destination DMA address: the user data buffer. */
        DMA0DA = (unsigned short)pBuffer;
        /* The size of the block to be transferred */
        DMA0SZ = count;
        /* Configure the DMA transfer*/
        DMA0CTL =
          DMAIE   |                         /* Enable interrupt */
          DMADT_0 |                         /* Single transfer mode */
          DMASBDB |                         /* Byte mode */
          DMAEN |                           /* Enable DMA */
          DMADSTINCR1 | DMADSTINCR0;        /* Increment the destination address */

        /* We depend on the DMA priorities here.  Both triggers occur at
           the same time, since the source is identical.  DMA0 is handled
           first, and retrieves the byte.  DMA1 is triggered next, and
           sends the next byte. */
        /* Source DMA address: constant 0xFF (don't increment)*/
        DMA1SA = U1TXBUF_;
        /* Destination DMA address: the transmit buffer. */
        DMA1DA = U1TXBUF_;
        /* Increment the destination address */
        /* The size of the block to be transferred */
        DMA1SZ = count-1;
        /* Configure the DMA transfer*/
        DMA1CTL =
          DMADT_0 |                         /* Single transfer mode */
          DMASBDB |                         /* Byte mode */
          DMAEN;                            /* Enable DMA */

        /* Kick off the transfer by sending the first byte */
        U1TXBUF = 0xFF;
//      while (DMA0CTL & DMAEN) _NOP(); //LPM0;  // wait till done
//      while (DMA0CTL & DMAEN) _EINT(); LPM0;  // wait till done
        _EINT(); LPM0;  // wait till done
#endif
        // get CRC bytes (not really needed by us, but required by MMC)
        spiSendByte(0xff);
        spiSendByte(0xff);
        rvalue = MMC_SUCCESS;
      }
      else
      {
        // the data token was never received
        rvalue = MMC_DATA_TOKEN_ERROR;      // 3
      }
    }
    else
    {
      // the MMC never acknowledge the read command
      rvalue = MMC_RESPONSE_ERROR;          // 2
    }
  }
  else
  {
    rvalue = MMC_BLOCK_SET_ERROR;           // 1
  }
  CS_HIGH ();
  spiSendByte(0xff);
  return rvalue;
}// mmc_read_block



//---------------------------------------------------------------------
//char mmcWriteBlock (const unsigned long address)
char mmcWriteBlock (const unsigned long address, const unsigned long count, unsigned char *pBuffer)
{
  unsigned long i = 0;
  char rvalue = MMC_RESPONSE_ERROR;         // MMC_SUCCESS;
  //  char c = 0x00;

  // Set the block length to read
  if (mmcSetBlockLength (count) == MMC_SUCCESS)   // block length could be set
  {
    // SS = LOW (on)
    CS_LOW ();
    // send write command
    mmcSendCmd (MMC_WRITE_BLOCK,address, 0xFF);

    // check if the MMC acknowledged the write block command
    // it will do this by sending an affirmative response
    // in the R1 format (0x00 is no errors)
    if (mmcGetXXResponse(MMC_R1_RESPONSE) == MMC_R1_RESPONSE)
    {
      spiSendByte(0xff);
      // send the data token to signify the start of the data
      spiSendByte(0xfe);
      // clock the actual data transfer and transmitt the bytes
#ifndef withDMA
      for (i = 0; i < count; i++)
        spiSendByte(pBuffer[i]);            
#else
      /* Get the block */
      /* DMA trigger is UART send */
      DMACTL0 &= ~(DMA0TSEL_15);
      DMACTL0 |= (DMA0TSEL_9);
      /* Source DMA address: the data buffer.  */
      DMA0SA = (unsigned short)pBuffer;
      /* Destination DMA address: the UART send register. */
      DMA0DA = U1TXBUF_;
      /* The size of the block to be transferred */
      DMA0SZ = count;
      /* Configure the DMA transfer*/
      DMA0CTL =
        DMAREQ  |                           /* start transfer */
        DMADT_0 |                           /* Single transfer mode */
        DMASBDB |                           /* Byte mode */
        DMAEN |                             /* Enable DMA */
        DMASRCINCR1 | DMASRCINCR0;          /* Increment the source address */
#endif
      // put CRC bytes (not really needed by us, but required by MMC)
      spiSendByte(0xff);
      spiSendByte(0xff);
      // read the data response xxx0<status>1 : status 010: Data accected, status 101: Data
      //   rejected due to a crc error, status 110: Data rejected due to a Write error.
      mmcCheckBusy();
      rvalue = MMC_SUCCESS;
    }
    else
    {
      // the MMC never acknowledge the write command
      rvalue = MMC_RESPONSE_ERROR;   // 2
    }
  }
  else
  {
    rvalue = MMC_BLOCK_SET_ERROR;   // 1
  }
  // give the MMC the required clocks to finish up what ever it needs to do
  //  for (i = 0; i < 9; ++i)
  //    spiSendByte(0xff);

  CS_HIGH ();
  // Send 8 Clock pulses of delay.
  spiSendByte(0xff);
  return rvalue;
} // mmc_write_block


//---------------------------------------------------------------------
void mmcSendCmd (const char cmd, unsigned long data, const char crc)
{
  char frame[6];
  char temp;
  int i;
  frame[0]=(cmd|0x40);
  for(i=3;i>=0;i--){
    temp=(char)(data>>(8*i));
    frame[4-i]=(temp);
  }
  frame[5]=(crc);
  for(i=0;i<6;i++)
    spiSendByte(frame[i]);
}


//--------------- set blocklength 2^n ------------------------------------------------------
char mmcSetBlockLength (const unsigned long blocklength)
{
  //  char rValue = MMC_TIMEOUT_ERROR;
  //  char i = 0;
  // SS = LOW (on)
  CS_LOW ();
  // Set the block length to read
  //MMC_SET_BLOCKLEN =CMD16
  mmcSendCmd(MMC_SET_BLOCKLEN, blocklength, 0xFF);

  // get response from MMC - make sure that its 0x00 (R1 ok response format)
  if(mmcGetResponse()!=0x00)
  { initMMC();
    mmcSendCmd(MMC_SET_BLOCKLEN, blocklength, 0xFF);
    mmcGetResponse();
  }

  CS_HIGH ();

  // Send 8 Clock pulses of delay.
  spiSendByte(0xff);

  return MMC_SUCCESS;
} // Set block_length


unsigned char spiSendByte(const unsigned char data)
{
  while ((IFG2&UTXIFG1) ==0);   // wait while not ready / for RX
  TXBUF1 = data;         // write
  while ((IFG2 & URXIFG1)==0);   // wait for RX buffer (full)
  return (RXBUF1);
}


// Reading the contents of the CSD and CID registers in SPI mode is a simple
// read-block transaction.
char mmcReadRegister (const char cmd_register, const unsigned char length, unsigned char *pBuffer)
{
  char uc = 0;
  char rvalue = MMC_TIMEOUT_ERROR;

  if (mmcSetBlockLength (length) == MMC_SUCCESS)
  {
    CS_LOW ();
    // CRC not used: 0xff as last byte
    mmcSendCmd(cmd_register, 0x000000, 0xff);

    // wait for response
    // in the R1 format (0x00 is no errors)
    if (mmcGetResponse() == 0x00)
    {
      if (mmcGetXXResponse(0xfe)== 0xfe)
        for (uc = 0; uc < length; uc++)
          pBuffer[uc] = spiSendByte(0xff);  //mmc_buffer[uc] = spiSendByte(0xff);
      // get CRC bytes (not really needed by us, but required by MMC)
      spiSendByte(0xff);
      spiSendByte(0xff);
      rvalue = MMC_SUCCESS;
    }
    else
      rvalue = MMC_RESPONSE_ERROR;
    // CS = HIGH (off)
    CS_HIGH ();

    // Send 8 Clock pulses of delay.
    spiSendByte(0xff);
  }
  CS_HIGH ();
  return rvalue;
} // mmc_read_register


#include "math.h"
unsigned long MMC_ReadCardSize(void)
{
  // Read contents of Card Specific Data (CSD)

  unsigned long MMC_CardSize;
  unsigned short i,      // index
                 j,      // index
                 b,      // temporary variable
                 response,   // MMC response to command
                 mmc_C_SIZE;

  unsigned char mmc_READ_BL_LEN,  // Read block length
                mmc_C_SIZE_MULT;

  CS_LOW ();

  spiSendByte(MMC_READ_CSD);   // CMD 9
  for(i=4; i>0; i--)      // Send four dummy bytes
    spiSendByte(0);
  spiSendByte(0xFF);   // Send CRC byte

  response = mmcGetResponse();

  // data transmission always starts with 0xFE
  b = spiSendByte(0xFF);

  if( !response )
  {
    while (b != 0xFE) b = spiSendByte(0xFF);
    // bits 127:87
    for(j=5; j>0; j--)          // Host must keep the clock running for at
      b = spiSendByte(0xff);


    // 4 bits of READ_BL_LEN
    // bits 84:80
    b =spiSendByte(0xff);  // lower 4 bits of CCC and
    mmc_READ_BL_LEN = b & 0x0F;

    b = spiSendByte(0xff);

    // bits 73:62  C_Size
    // xxCC CCCC CCCC CC
    mmc_C_SIZE = (b & 0x03) << 10;
    b = spiSendByte(0xff);
    mmc_C_SIZE += b << 2;
    b = spiSendByte(0xff);
    mmc_C_SIZE += b >> 6;

    // bits 55:53
    b = spiSendByte(0xff);

    // bits 49:47
    mmc_C_SIZE_MULT = (b & 0x03) << 1;
    b = spiSendByte(0xff);
    mmc_C_SIZE_MULT += b >> 7;

    // bits 41:37
    b = spiSendByte(0xff);

    b = spiSendByte(0xff);

    b = spiSendByte(0xff);

    b = spiSendByte(0xff);

    b = spiSendByte(0xff);

  }

  for(j=4; j>0; j--)          // Host must keep the clock running for at
    b = spiSendByte(0xff);  // least Ncr (max = 4 bytes) cycles after
                               // the card response is received
  b = spiSendByte(0xff);
  CS_LOW ();

  MMC_CardSize = (mmc_C_SIZE + 1);
  // power function with base 2 is better with a loop
  // i = (pow(2,mmc_C_SIZE_MULT+2)+0.5);
  for(i = 2,j=mmc_C_SIZE_MULT+2; j>1; j--)
    i <<= 1;
  MMC_CardSize *= i;
  // power function with base 2 is better with a loop
  //i = (pow(2,mmc_READ_BL_LEN)+0.5);
  for(i = 2,j=mmc_READ_BL_LEN; j>1; j--)
    i <<= 1;
  MMC_CardSize *= i;

  return (MMC_CardSize);

}


char mmc_ping(void)
{
  if (!(P5IN & 0x01))
    return (MMC_SUCCESS);
  else
    return (MMC_INIT_ERROR);
}


#ifdef withDMA
#ifdef __IAR_SYSTEMS_ICC__
#if __VER__ < 200
interrupt[DACDMA_VECTOR] void DMA_isr(void)
#else
#pragma vector = DACDMA_VECTOR
__interrupt void DMA_isr(void)
#endif
#endif

#ifdef __CROSSWORKS__
void DMA_isr(void)   __interrupt[DACDMA_VECTOR]
#endif

#ifdef __TI_COMPILER_VERSION__
__interrupt void DMA_isr(void);
DMA_ISR(DMA_isr)
__interrupt void DMA_isr(void)
#endif
{
  DMA0CTL &= ~(DMAIFG);
  LPM3_EXIT;
}
#endif


//---------------------------------------------------------------------
#endif /* _MMCLIB_C */


file: /Techref/ti/msp430/rwsdmmc/mmc.c, 20KB, , updated: 2006/1/17 15:25, local time: 2024/11/15 05:08,
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