mcc_int.c

ANSI C 源代码 WISD MSC8101的MCC驱动程序

/****************************************************************************
* Property of Motorola, Wireless Infrastructure Systems Division
****************************************************************************
* ANSI C source code
*
* MCC Driver for WISD MSC8101 Driver Library
*
* MOTOROLA GENERAL BUSINESS INFORMATION
****************************************************************************/


/****************************************************************************
*
* MODULE NAME: mcc_int.c  
*
*****************************************************************************
* DESCRIPTION: 
*     This file contains the interrupt drivers and related routines  
*     for MCC1 and MCC2. Each Rx interrupt performs a data check on the 
*     received data to ensure integrity. 
* 
*     If MCC1_TEST= 1 (TRUE) then MCC1 will be the MCC used in the test.
*     The green LED will flash to indicate MCC1 receive interrupts are ongoing
*     and that the receive interrupt based data check is successful. 
*        LD10 : S-0    : Green ; Indicates successful test result.
*
*     If MCC1_TEST= 0 (FALSE) then MCC2 will be the MCC used in the test.
*     The red LED will flash to indicate MCC2 receive interrupts are ongoing
*     and that the receive interrupt based data check is successful. 
*        LD9  : S-1    : Red   ; Indicates successful test result.
*
*
* AUTHOR:     Jim Gilbert.
*
* VERSION:    v1.0, 20 Dec 2001.
*
* COMPILER:   Metrowerks, CodeWarrior for Starcore Release 1.0
*             IDE v4.1 Build 696.
*
* TARGET:     StarCore/MSC8101 ADS.
*
* REVISION HISTORY: initial release v0.1, 01 Aug  2001.
*                                   v1.0, 20 Dec  2001.
*****************************************************************************/

/*****************************************************************************
* Include files
*****************************************************************************/

#include "msc8101ads.h"      //MSC8101ADS specific settings and functions
#include "msc8101.h"
#include "mcc_int.h"         //local header file 
#include "mcc.h"             //Mcc driver functions header file 


/*****************************************************************************
* Global variables                                                          
*****************************************************************************/

// MCC1 Buffer handling counters 
static UWord16   gusiMcc1Rint0Ctr=0;             //MCC Receive Interrupt Ring 
static UWord16   gusiMcc1TintCtr=0;              //MCC Transmit Interrupt Ring
static UWord16   gusiMcc1RxbufCtr[MCC1_NUM_CH];  //Receive Buffers
static UWord16   gusiMcc1TxbufCtr[MCC1_NUM_CH];  //Transmit Buffers
static UWord16   gusiMcc1RxIrqCtr[MCC1_NUM_CH];  //Receive Interrupt counter
static UWord16   gusiMcc1TxIrqCtr[MCC1_NUM_CH];  //Transmit Interrupt counter

// MCC2 Buffer handling counters 
static UWord16   gusiMcc2Rint0Ctr=0;             //MCC Receive Interrupt Ring 
static UWord16   gusiMcc2TintCtr=0;              //MCC Transmit Interrupt Ring
static UWord16   gusiMcc2RxbufCtr[MCC2_NUM_CH];  //Receive Buffers
static UWord16   gusiMcc2TxbufCtr[MCC2_NUM_CH];  //Transmit Buffers
static UWord16   gusiMcc2RxIrqCtr[MCC2_NUM_CH];  //Receive Interrupt counter
static UWord16   gusiMcc2TxIrqCtr[MCC2_NUM_CH];  //Transmit Interrupt counter

// Debug Aids - Interrupt Counters
static UWord16   gusiMcc1RxIntcount=0;
static UWord16   gusiMcc1TxIntcount=0;
static UWord16   gusiMcc1TotalIntcount=0;
static UWord16   gusiMcc2RxIntcount=0;
static UWord16   gusiMcc2TxIntcount=0;
static UWord16   gusiMcc2TotalIntcount=0;


/*****************************************************************************
* FUNCTION: PrepareOpenMcc1Channel()
* PURPOSE:  Initialises parameters and variables specific to a channel.           
* NOTES:    None.
* ENTRY:    ucChanI - Channel Number.
* EXIT:     None. 
*****************************************************************************/
void PrepareOpenMcc1Channel(UByte ucChanI)
{
  MCC1_InitSpecific(ucChanI);  //Initialize channel specific parameters;
  gusiMcc1RxbufCtr[ucChanI]=0;
  gusiMcc1TxbufCtr[ucChanI]=0;
  gusiMcc1RxIrqCtr[ucChanI]=0; //for debugging/counting interrupts only
  gusiMcc1TxIrqCtr[ucChanI]=0;
  
  return;
}


/*****************************************************************************
* FUNCTION: PrepareOpenMcc2Channel()
* PURPOSE:  Initialises parameters and variables specific to a channel.           
* NOTES:    None.
* ENTRY:    ucChanI - Channel Number.
* EXIT:     None. 
*****************************************************************************/
void PrepareOpenMcc2Channel(UByte ucChanI)
{
  MCC2_InitSpecific(ucChanI);  //Initialize channel specific parameters;
  gusiMcc2RxbufCtr[ucChanI]=0;
  gusiMcc2TxbufCtr[ucChanI]=0;
  gusiMcc2RxIrqCtr[ucChanI]=0; //for debugging/counting interrupts only
  gusiMcc2TxIrqCtr[ucChanI]=0;
  
  return;
}


/*****************************************************************************
* FUNCTION: MCC1_Interrupt()
* PURPOSE:  Manages MCC1 interrupts, Tx/Rx BDs and checks loopback data.           
* NOTES:    None.
* ENTRY:    None
* EXIT:     None. 
*****************************************************************************/
#pragma interrupt MCC1_Interrupt()
void MCC1_Interrupt(void)
{
  /*
    This function is only called when a SIC/MCC1 interrupt occurs.
  */
  
  UWord32*  puliMCC1IrqTableBase;
  t_Mcc1BDRings*  pstMCC1;
  UByte   ucChan;
  UWord16 usiMCCE;
  Word16  i,pass, status;
  t_8101IMM *pstIMM = (t_8101IMM*)IMM_BASE;        // Pointer to internal memory

  pstIMM->t_aIORegs[PORTA].vuliPDat ^= 0x00000008; //toggle PA28 output (logic analyzer)  

  usiMCCE=pstIMM->t_aSIRegs[MCC1].vusiMCCE;        //read event cause
  if(!(usiMCCE & 0x4000) && !(usiMCCE & 0x0004))   //Catch Unintentional Interrupts
    asm(" debug");   
   
  
  /*************/
  /*** RINT0 ***/
  /*************/
  if (usiMCCE & 0x4000) //RINT0 interrupt?
  { 
    pstMCC1 = (t_Mcc1BDRings*)(MCC1_BDRINGS_BASE-LOCAL_BASE);    
    puliMCC1IrqTableBase = (UWord32*)(MCC1_RINT0_BASE-LOCAL_BASE);
    
    pstIMM->t_aSIRegs[MCC1].vusiMCCE = 0x4000; //clear RINT0 irq flag in MCCE2-reg.

    // Read Int Q entry from core side
    while(*(puliMCC1IrqTableBase+gusiMcc1Rint0Ctr)&0x80000000)
    {
      if (*(puliMCC1IrqTableBase+gusiMcc1Rint0Ctr) & 0x00020000)
        asm(" debug");                          // BSY indicates an overrun

      //get channel number from bits 18-25:
      ucChan = (UByte)(*(puliMCC1IrqTableBase+gusiMcc1Rint0Ctr)>>6);
      *(puliMCC1IrqTableBase+gusiMcc1Rint0Ctr) &= 0x40000000; //Reset irq circ. table entry
      pstIMM->t_aIORegs[PORTA].vuliPDat |= ucChan&0x00000007; //sets up PA29-31 with chan-code 

      if (ucChan<MCC1_NUM_CH)
      {

        /*-----------------------------------------------*/
        /* Multiple Buffer and BD Handling per Interrupt */
        /*-----------------------------------------------*/
        
        // If handling one buffer per IRQ then simple -> clear the BD
        // However handling multi buffers per frame/subframe interrupt...             
        // So, clear BDs between the current interrupt & previous one handled
        i=gusiMcc1RxbufCtr[ucChan];
        for(;;)
        {
          /*-----------------------------------------------*/
          /* COMPARE RX BUFFER WITH TX BUFFER              */
          /*-----------------------------------------------*/
          pass=CompareBuffers((UByte*)(pstMCC1->astRxChan[ucChan].astBufD[i].uliBdAddr - LOCAL_BASE),
                              (UByte*)(pstMCC1->astTxChan[ucChan].astBufD[i].uliBdAddr - LOCAL_BASE),
                              (UByte )pstMCC1->astTxChan[ucChan].astBufD[i].usiBdLength);

          if (!pass) 
          {
            LED(GREEN_OFF);
            asm(" debug");
          }
       
          /*-----------------------------------------------*/
          /* Clear BDs between this int and previous one   */
          /*-----------------------------------------------*/
          pstMCC1->astRxChan[ucChan].astBufD[i].usiBdCstatus |= 0x8000;
          pstMCC1->astRxChan[ucChan].astBufD[i].usiBdLength = 0;          
          status = pstMCC1->astRxChan[ucChan].astBufD[i].usiBdCstatus;
          if (status & 0x2000)  // if wrap set, wrap count
            i=0; 
          else
            i++;
          if (status & 0x1000)  // if interrupt, finish
            break;
        }                                            

        // Update buffer counter record 
        gusiMcc1RxbufCtr[ucChan] = i;
      }
      else
      {
        //wrong channel number
        asm(" debug");
      }
      if (++gusiMcc1Rint0Ctr==MCC1_RINT0_NUM) gusiMcc1Rint0Ctr=0;

      pstIMM->t_aIORegs[PORTA].vuliPDat &= ~0x00000007;//resets PA29-31 to 0

      gusiMcc1RxIntcount++;        // debug aid
      gusiMcc1RxIrqCtr[ucChan]++;  // debug aid                            
        
    }
  }      
  

  /*************/
  /*** TINT  ***/
  /*************/
  if (usiMCCE & 0x0004)  // TINT Interrupt
  {
    pstMCC1 = (t_Mcc1BDRings*)(MCC1_BDRINGS_BASE-LOCAL_BASE);    
    puliMCC1IrqTableBase = (UWord32*)(MCC1_TINT_BASE-LOCAL_BASE);

    pstIMM->t_aSIRegs[MCC1].vusiMCCE = 0x0004; //clear TINT irq flag in MCCE1-reg.

    // Read Int Q entry from core side
    while(*(puliMCC1IrqTableBase+gusiMcc1TintCtr)&0x80000000)
    {
    
      if (*(puliMCC1IrqTableBase+gusiMcc1Rint0Ctr) & 0x00200000)
        asm(" debug"); // UN indicates an underrun

      //get channel number from bits 18-25:
      ucChan = (UByte)(*(puliMCC1IrqTableBase+gusiMcc1TintCtr)>>6);
      *(puliMCC1IrqTableBase+gusiMcc1TintCtr) &= 0x40000000; //Reset irq circ. table entry
//    pstIMM->t_aIORegs[PORTA].vuliPDat |= ucChan&0x00000007;//sets up PA29-31 with chan-code 
 
      if (ucChan<MCC1_NUM_CH)
      {       
        /*-----------------------------------------------*/
        /* Multiple Buffer and BD Handling per Interrupt */
        /*-----------------------------------------------*/