cpu/ixp/npe/IxNpeMhConfig.c - github/trini/u-boot - Gitiles

 /**
  * @file IxNpeMhConfig.c
  *
  * @author Intel Corporation
  * @date 18 Jan 2002
  *
  * @brief This file contains the implementation of the private API for the
  * Configuration module.
  *
  *
  * @par
  * IXP400 SW Release version 2.0
  *
  * -- Copyright Notice --
  *
  * @par
  * Copyright 2001-2005, Intel Corporation.
  * All rights reserved.
  *
  * @par
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  * 3. Neither the name of the Intel Corporation nor the names of its contributors
  *    may be used to endorse or promote products derived from this software
  *    without specific prior written permission.
  *
  * @par
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ``AS IS''
  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
  * ARE DISCLAIMED.  IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS 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.
  *
  * @par
  * -- End of Copyright Notice --
 */

 /*
  * Put the system defined include files required.
  */


 /*
  * Put the user defined include files required.
  */

 #include "IxOsal.h"

 #include "IxNpeMhMacros_p.h"

 #include "IxNpeMhConfig_p.h"

 /*
  * #defines and macros used in this file.
  */
 #define IX_NPE_MH_MAX_NUM_OF_RETRIES 1000000 /**< Maximum number of
                                               * retries before
                                               * timeout
 					                          */

 /*
  * Typedefs whose scope is limited to this file.
  */

 /**
  * @struct IxNpeMhConfigStats
  *
  * @brief This structure is used to maintain statistics for the
  * Configuration module.
  */

 typedef struct
 {
     UINT32 outFifoReads;        /**< outFifo reads */
     UINT32 inFifoWrites;        /**< inFifo writes */
     UINT32 maxInFifoFullRetries;   /**< max retries if inFIFO full   */
     UINT32 maxOutFifoEmptyRetries; /**< max retries if outFIFO empty */
 } IxNpeMhConfigStats;

 /*
  * Variable declarations global to this file only.  Externs are followed by
  * static variables.
  */

 IxNpeMhConfigNpeInfo ixNpeMhConfigNpeInfo[IX_NPEMH_NUM_NPES] =
 {
     {
         0,
         IX_NPEMH_NPEA_INT,
 	0,
         0,
         0,
         0,
         0,
         NULL,
         FALSE
     },
     {
         0,
         IX_NPEMH_NPEB_INT,
 	0,
 	0,
         0,
         0,
         0,
         NULL,
         FALSE
     },
     {
         0,
         IX_NPEMH_NPEC_INT,
         0,
         0,
         0,
         0,
         0,
         NULL,
         FALSE
     }
 };

 PRIVATE IxNpeMhConfigStats ixNpeMhConfigStats[IX_NPEMH_NUM_NPES];

 /*
  * Extern function prototypes.
  */

 /*
  * Static function prototypes.
  */
 PRIVATE
 void ixNpeMhConfigIsr (void *parameter);

 /*
  * Function definition: ixNpeMhConfigIsr
  */

 PRIVATE
 void ixNpeMhConfigIsr (void *parameter)
 {
     IxNpeMhNpeId npeId = (IxNpeMhNpeId)parameter;
     UINT32 ofint;
     volatile UINT32 *statusReg =
         (UINT32 *)ixNpeMhConfigNpeInfo[npeId].statusRegister;

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
                      "ixNpeMhConfigIsr\n");

     /* get the OFINT (OutFifo interrupt) bit of the status register */
     IX_NPEMH_REGISTER_READ_BITS (statusReg, &ofint, IX_NPEMH_NPE_STAT_OFINT);

     /* if the OFINT status bit is set */
     if (ofint)
     {
         /* if there is an ISR registered for this NPE */
         if (ixNpeMhConfigNpeInfo[npeId].isr != NULL)
         {
             /* invoke the ISR routine */
             ixNpeMhConfigNpeInfo[npeId].isr (npeId);
         }
         else
         {
             /* if we don't service the interrupt the NPE will continue */
             /* to trigger the interrupt indefinitely */
             IX_NPEMH_ERROR_REPORT ("No ISR registered to service "
                                    "interrupt\n");
         }
     }

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
                      "ixNpeMhConfigIsr\n");
 }

 /*
  * Function definition: ixNpeMhConfigInitialize
  */

 void ixNpeMhConfigInitialize (
     IxNpeMhNpeInterrupts npeInterrupts)
 {
     IxNpeMhNpeId npeId;
     UINT32 virtualAddr[IX_NPEMH_NUM_NPES];

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
                      "ixNpeMhConfigInitialize\n");

     /* Request a mapping for the NPE-A config register address space */
     virtualAddr[IX_NPEMH_NPEID_NPEA] =
 	(UINT32) IX_OSAL_MEM_MAP (IX_NPEMH_NPEA_BASE,
 				     IX_OSAL_IXP400_NPEA_MAP_SIZE);
     IX_OSAL_ASSERT (virtualAddr[IX_NPEMH_NPEID_NPEA]);

     /* Request a mapping for the NPE-B config register address space */
     virtualAddr[IX_NPEMH_NPEID_NPEB] =
 	(UINT32) IX_OSAL_MEM_MAP (IX_NPEMH_NPEB_BASE,
 				     IX_OSAL_IXP400_NPEB_MAP_SIZE);
     IX_OSAL_ASSERT (virtualAddr[IX_NPEMH_NPEID_NPEB]);

     /* Request a mapping for the NPE-C config register address space */
     virtualAddr[IX_NPEMH_NPEID_NPEC] =
 	(UINT32) IX_OSAL_MEM_MAP (IX_NPEMH_NPEC_BASE,
 				     IX_OSAL_IXP400_NPEC_MAP_SIZE);
     IX_OSAL_ASSERT (virtualAddr[IX_NPEMH_NPEID_NPEC]);

     /* for each NPE ... */
     for (npeId = 0; npeId < IX_NPEMH_NUM_NPES; npeId++)
     {
         /* declare a convenience pointer */
         IxNpeMhConfigNpeInfo *npeInfo = &ixNpeMhConfigNpeInfo[npeId];

 	/* store the virtual addresses of the NPE registers for later use */
 	npeInfo->virtualRegisterBase  = virtualAddr[npeId];
 	npeInfo->statusRegister  = virtualAddr[npeId] + IX_NPEMH_NPESTAT_OFFSET;
 	npeInfo->controlRegister = virtualAddr[npeId] + IX_NPEMH_NPECTL_OFFSET;
 	npeInfo->inFifoRegister  = virtualAddr[npeId] + IX_NPEMH_NPEFIFO_OFFSET;
 	npeInfo->outFifoRegister = virtualAddr[npeId] + IX_NPEMH_NPEFIFO_OFFSET;

         /* for test purposes - to verify the register addresses */
         IX_NPEMH_TRACE2 (IX_NPEMH_DEBUG, "NPE %d status register  = "
                          "0x%08X\n", npeId, npeInfo->statusRegister);
         IX_NPEMH_TRACE2 (IX_NPEMH_DEBUG, "NPE %d control register = "
                          "0x%08X\n", npeId, npeInfo->controlRegister);
         IX_NPEMH_TRACE2 (IX_NPEMH_DEBUG, "NPE %d inFifo register  = "
                          "0x%08X\n", npeId, npeInfo->inFifoRegister);
         IX_NPEMH_TRACE2 (IX_NPEMH_DEBUG, "NPE %d outFifo register = "
                          "0x%08X\n", npeId, npeInfo->outFifoRegister);

         /* connect our ISR to the NPE interrupt */
         (void) ixOsalIrqBind (
             npeInfo->interruptId, ixNpeMhConfigIsr, (void *)npeId);

         /* initialise a mutex for this NPE */
         (void) ixOsalMutexInit (&npeInfo->mutex);

         /* if we should service the NPE's "outFIFO not empty" interrupt */
         if (npeInterrupts == IX_NPEMH_NPEINTERRUPTS_YES)
         {
             /* enable the NPE's "outFIFO not empty" interrupt */
             ixNpeMhConfigNpeInterruptEnable (npeId);
         }
         else
         {
             /* disable the NPE's "outFIFO not empty" interrupt */
             ixNpeMhConfigNpeInterruptDisable (npeId);
         }
     }

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
                      "ixNpeMhConfigInitialize\n");
 }

 /*
  * Function definition: ixNpeMhConfigUninit
  */

 void ixNpeMhConfigUninit (void)
 {
     IxNpeMhNpeId npeId;

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
                      "ixNpeMhConfigUninit\n");

     /* for each NPE ... */
     for (npeId = 0; npeId < IX_NPEMH_NUM_NPES; npeId++)
     {
         /* declare a convenience pointer */
         IxNpeMhConfigNpeInfo *npeInfo = &ixNpeMhConfigNpeInfo[npeId];

         /* disconnect ISR */
         ixOsalIrqUnbind(npeInfo->interruptId);

         /* destroy mutex associated with this NPE */
         ixOsalMutexDestroy(&npeInfo->mutex);

 	IX_OSAL_MEM_UNMAP (npeInfo->virtualRegisterBase);

 	npeInfo->virtualRegisterBase  = 0;
 	npeInfo->statusRegister  = 0;
 	npeInfo->controlRegister = 0;
 	npeInfo->inFifoRegister  = 0;
 	npeInfo->outFifoRegister = 0;
     }

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
                      "ixNpeMhConfigUninit\n");
 }

 /*
  * Function definition: ixNpeMhConfigIsrRegister
  */

 void ixNpeMhConfigIsrRegister (
     IxNpeMhNpeId npeId,
     IxNpeMhConfigIsr isr)
 {
     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
                      "ixNpeMhConfigIsrRegister\n");

     /* check if there is already an ISR registered for this NPE */
     if (ixNpeMhConfigNpeInfo[npeId].isr != NULL)
     {
         IX_NPEMH_TRACE0 (IX_NPEMH_DEBUG, "Over-writing registered NPE ISR\n");
     }

     /* save the ISR routine with the NPE info */
     ixNpeMhConfigNpeInfo[npeId].isr = isr;

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
                      "ixNpeMhConfigIsrRegister\n");
 }

 /*
  * Function definition: ixNpeMhConfigNpeInterruptEnable
  */

 BOOL ixNpeMhConfigNpeInterruptEnable (
     IxNpeMhNpeId npeId)
 {
     UINT32 ofe;
     volatile UINT32 *controlReg =
         (UINT32 *)ixNpeMhConfigNpeInfo[npeId].controlRegister;

     /* get the OFE (OutFifoEnable) bit of the control register */
     IX_NPEMH_REGISTER_READ_BITS (controlReg, &ofe, IX_NPEMH_NPE_CTL_OFE);

     /* if the interrupt is disabled then we must enable it */
     if (!ofe)
     {
         /* set the OFE (OutFifoEnable) bit of the control register */
         /* we must set the OFEWE (OutFifoEnableWriteEnable) at the same */
         /* time for the write to have effect */
         IX_NPEMH_REGISTER_WRITE_BITS (controlReg,
                                       (IX_NPEMH_NPE_CTL_OFE |
                                        IX_NPEMH_NPE_CTL_OFEWE),
                                       (IX_NPEMH_NPE_CTL_OFE |
                                        IX_NPEMH_NPE_CTL_OFEWE));
     }

     /* return the previous state of the interrupt */
     return (ofe != 0);
 }

 /*
  * Function definition: ixNpeMhConfigNpeInterruptDisable
  */

 BOOL ixNpeMhConfigNpeInterruptDisable (
     IxNpeMhNpeId npeId)
 {
     UINT32 ofe;
     volatile UINT32 *controlReg =
         (UINT32 *)ixNpeMhConfigNpeInfo[npeId].controlRegister;

     /* get the OFE (OutFifoEnable) bit of the control register */
     IX_NPEMH_REGISTER_READ_BITS (controlReg, &ofe, IX_NPEMH_NPE_CTL_OFE);

     /* if the interrupt is enabled then we must disable it */
     if (ofe)
     {
         /* unset the OFE (OutFifoEnable) bit of the control register */
         /* we must set the OFEWE (OutFifoEnableWriteEnable) at the same */
         /* time for the write to have effect */
         IX_NPEMH_REGISTER_WRITE_BITS (controlReg,
                                       (0                    |
                                        IX_NPEMH_NPE_CTL_OFEWE),
                                       (IX_NPEMH_NPE_CTL_OFE |
                                        IX_NPEMH_NPE_CTL_OFEWE));
     }

     /* return the previous state of the interrupt */
     return (ofe != 0);
 }

 /*
  * Function definition: ixNpeMhConfigMessageIdGet
  */

 IxNpeMhMessageId ixNpeMhConfigMessageIdGet (
     IxNpeMhMessage message)
 {
     /* return the most-significant byte of the first word of the */
     /* message */
     return ((IxNpeMhMessageId) ((message.data[0] >> 24) & 0xFF));
 }

 /*
  * Function definition: ixNpeMhConfigNpeIdIsValid
  */

 BOOL ixNpeMhConfigNpeIdIsValid (
     IxNpeMhNpeId npeId)
 {
     /* check that the npeId parameter is within the range of valid IDs */
     return (npeId >= 0 && npeId < IX_NPEMH_NUM_NPES);
 }

 /*
  * Function definition: ixNpeMhConfigLockGet
  */

 void ixNpeMhConfigLockGet (
     IxNpeMhNpeId npeId)
 {
     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
                      "ixNpeMhConfigLockGet\n");

     /* lock the mutex for this NPE */
     (void) ixOsalMutexLock (&ixNpeMhConfigNpeInfo[npeId].mutex,
 			    IX_OSAL_WAIT_FOREVER);

     /* disable the NPE's "outFIFO not empty" interrupt */
     ixNpeMhConfigNpeInfo[npeId].oldInterruptState =
         ixNpeMhConfigNpeInterruptDisable (npeId);

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
                      "ixNpeMhConfigLockGet\n");
 }

 /*
  * Function definition: ixNpeMhConfigLockRelease
  */

 void ixNpeMhConfigLockRelease (
     IxNpeMhNpeId npeId)
 {
     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
                      "ixNpeMhConfigLockRelease\n");

     /* if the interrupt was previously enabled */
     if (ixNpeMhConfigNpeInfo[npeId].oldInterruptState)
     {
         /* enable the NPE's "outFIFO not empty" interrupt */
         ixNpeMhConfigNpeInfo[npeId].oldInterruptState =
             ixNpeMhConfigNpeInterruptEnable (npeId);
     }

     /* unlock the mutex for this NPE */
     (void) ixOsalMutexUnlock (&ixNpeMhConfigNpeInfo[npeId].mutex);

     IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
                      "ixNpeMhConfigLockRelease\n");
 }

 /*
  * Function definition: ixNpeMhConfigInFifoWrite
  */

 IX_STATUS ixNpeMhConfigInFifoWrite (
     IxNpeMhNpeId npeId,
     IxNpeMhMessage message)
 {
     volatile UINT32 *npeInFifo =
         (UINT32 *)ixNpeMhConfigNpeInfo[npeId].inFifoRegister;
     UINT32 retriesCount = 0;

     /* write the first word of the message to the NPE's inFIFO */
     IX_NPEMH_REGISTER_WRITE (npeInFifo, message.data[0]);

     /* need to wait for room to write second word - see SCR #493,
        poll for maximum number of retries, if exceed maximum
        retries, exit from while loop */
     while ((IX_NPE_MH_MAX_NUM_OF_RETRIES > retriesCount)
         && ixNpeMhConfigInFifoIsFull (npeId))
     {
         retriesCount++;
     }

     /* Return TIMEOUT status to caller, indicate that NPE Hang / Halt */
     if (IX_NPE_MH_MAX_NUM_OF_RETRIES == retriesCount)
     {
         return IX_NPEMH_CRITICAL_NPE_ERR;
     }

     /* write the second word of the message to the NPE's inFIFO */
     IX_NPEMH_REGISTER_WRITE (npeInFifo, message.data[1]);

     /* record in the stats the maximum number of retries needed */
     if (ixNpeMhConfigStats[npeId].maxInFifoFullRetries < retriesCount)
     {
 	ixNpeMhConfigStats[npeId].maxInFifoFullRetries = retriesCount;
     }

     /* update statistical info */
     ixNpeMhConfigStats[npeId].inFifoWrites++;

     return IX_SUCCESS;
 }

 /*
  * Function definition: ixNpeMhConfigOutFifoRead
  */

 IX_STATUS ixNpeMhConfigOutFifoRead (
     IxNpeMhNpeId npeId,
     IxNpeMhMessage *message)
 {
     volatile UINT32 *npeOutFifo =
         (UINT32 *)ixNpeMhConfigNpeInfo[npeId].outFifoRegister;
     UINT32 retriesCount = 0;

     /* read the first word of the message from the NPE's outFIFO */
     IX_NPEMH_REGISTER_READ (npeOutFifo, &message->data[0]);

     /* need to wait for NPE to write second word - see SCR #493
        poll for maximum number of retries, if exceed maximum
        retries, exit from while loop */
     while ((IX_NPE_MH_MAX_NUM_OF_RETRIES > retriesCount)
         && ixNpeMhConfigOutFifoIsEmpty (npeId))
     {
         retriesCount++;
     }

     /* Return TIMEOUT status to caller, indicate that NPE Hang / Halt */
     if (IX_NPE_MH_MAX_NUM_OF_RETRIES == retriesCount)
     {
         return IX_NPEMH_CRITICAL_NPE_ERR;
     }

     /* read the second word of the message from the NPE's outFIFO */
     IX_NPEMH_REGISTER_READ (npeOutFifo, &message->data[1]);

     /* record in the stats the maximum number of retries needed */
     if (ixNpeMhConfigStats[npeId].maxOutFifoEmptyRetries < retriesCount)
     {
 	ixNpeMhConfigStats[npeId].maxOutFifoEmptyRetries = retriesCount;
     }

     /* update statistical info */
     ixNpeMhConfigStats[npeId].outFifoReads++;

     return IX_SUCCESS;
 }

 /*
  * Function definition: ixNpeMhConfigShow
  */

 void ixNpeMhConfigShow (
     IxNpeMhNpeId npeId)
 {
     /* show the message fifo read counter */
     IX_NPEMH_SHOW ("Message FIFO reads",
                    ixNpeMhConfigStats[npeId].outFifoReads);

     /* show the message fifo write counter */
     IX_NPEMH_SHOW ("Message FIFO writes",
                    ixNpeMhConfigStats[npeId].inFifoWrites);

     /* show the max retries performed when inFIFO full */
     IX_NPEMH_SHOW ("Max inFIFO Full retries",
 		   ixNpeMhConfigStats[npeId].maxInFifoFullRetries);

     /* show the max retries performed when outFIFO empty */
     IX_NPEMH_SHOW ("Max outFIFO Empty retries",
 		   ixNpeMhConfigStats[npeId].maxOutFifoEmptyRetries);

     /* show the current status of the inFifo */
     ixOsalLog (IX_OSAL_LOG_LVL_USER, IX_OSAL_LOG_DEV_STDOUT,
 	       "InFifo is %s and %s\n",
 	       (ixNpeMhConfigInFifoIsEmpty (npeId) ?
 		(int) "EMPTY" : (int) "NOT EMPTY"),
 	       (ixNpeMhConfigInFifoIsFull (npeId) ?
 		(int) "FULL" : (int) "NOT FULL"),
 	       0, 0, 0, 0);

     /* show the current status of the outFifo */
     ixOsalLog (IX_OSAL_LOG_LVL_USER, IX_OSAL_LOG_DEV_STDOUT,
 	       "OutFifo is %s and %s\n",
 	       (ixNpeMhConfigOutFifoIsEmpty (npeId) ?
 		(int) "EMPTY" : (int) "NOT EMPTY"),
 	       (ixNpeMhConfigOutFifoIsFull (npeId) ?
 		(int) "FULL" : (int) "NOT FULL"),
 	       0, 0, 0, 0);
 }

 /*
  * Function definition: ixNpeMhConfigShowReset
  */

 void ixNpeMhConfigShowReset (
     IxNpeMhNpeId npeId)
 {
     /* reset the message fifo read counter */
     ixNpeMhConfigStats[npeId].outFifoReads = 0;

     /* reset the message fifo write counter */
     ixNpeMhConfigStats[npeId].inFifoWrites = 0;

     /* reset the max inFIFO Full retries counter */
     ixNpeMhConfigStats[npeId].maxInFifoFullRetries = 0;

     /* reset the max outFIFO empty retries counter */
     ixNpeMhConfigStats[npeId].maxOutFifoEmptyRetries = 0;
 }
	/**
	* @file IxNpeMhConfig.c
	*
	* @author Intel Corporation
	* @date 18 Jan 2002
	*
	* @brief This file contains the implementation of the private API for the
	* Configuration module.
	*
	*
	* @par
	* IXP400 SW Release version 2.0
	*
	* -- Copyright Notice --
	*
	* @par
	* Copyright 2001-2005, Intel Corporation.
	* All rights reserved.
	*
	* @par
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	* 3. Neither the name of the Intel Corporation nor the names of its contributors
	* may be used to endorse or promote products derived from this software
	* without specific prior written permission.
	*
	* @par
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ``AS IS''
	* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS 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.
	*
	* @par
	* -- End of Copyright Notice --
	*/

	/*
	* Put the system defined include files required.
	*/


	/*
	* Put the user defined include files required.
	*/

	#include "IxOsal.h"

	#include "IxNpeMhMacros_p.h"

	#include "IxNpeMhConfig_p.h"

	/*
	* #defines and macros used in this file.
	*/
	#define IX_NPE_MH_MAX_NUM_OF_RETRIES 1000000 /**< Maximum number of
	* retries before
	* timeout
	*/

	/*
	* Typedefs whose scope is limited to this file.
	*/

	/**
	* @struct IxNpeMhConfigStats
	*
	* @brief This structure is used to maintain statistics for the
	* Configuration module.
	*/

	typedef struct
	{
	UINT32 outFifoReads; /*< outFifo reads /
	UINT32 inFifoWrites; /*< inFifo writes /
	UINT32 maxInFifoFullRetries; /*< max retries if inFIFO full /
	UINT32 maxOutFifoEmptyRetries; /*< max retries if outFIFO empty /
	} IxNpeMhConfigStats;

	/*
	* Variable declarations global to this file only. Externs are followed by
	* static variables.
	*/

	IxNpeMhConfigNpeInfo ixNpeMhConfigNpeInfo[IX_NPEMH_NUM_NPES] =
	{
	{
	0,
	IX_NPEMH_NPEA_INT,
	0,
	0,
	0,
	0,
	0,
	NULL,
	FALSE
	},
	{
	0,
	IX_NPEMH_NPEB_INT,
	0,
	0,
	0,
	0,
	0,
	NULL,
	FALSE
	},
	{
	0,
	IX_NPEMH_NPEC_INT,
	0,
	0,
	0,
	0,
	0,
	NULL,
	FALSE
	}
	};

	PRIVATE IxNpeMhConfigStats ixNpeMhConfigStats[IX_NPEMH_NUM_NPES];

	/*
	* Extern function prototypes.
	*/

	/*
	* Static function prototypes.
	*/
	PRIVATE
	void ixNpeMhConfigIsr (void *parameter);

	/*
	* Function definition: ixNpeMhConfigIsr
	*/

	PRIVATE
	void ixNpeMhConfigIsr (void *parameter)
	{
	IxNpeMhNpeId npeId = (IxNpeMhNpeId)parameter;
	UINT32 ofint;
	volatile UINT32 *statusReg =
	(UINT32 *)ixNpeMhConfigNpeInfo[npeId].statusRegister;

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
	"ixNpeMhConfigIsr\n");

	/* get the OFINT (OutFifo interrupt) bit of the status register */
	IX_NPEMH_REGISTER_READ_BITS (statusReg, &ofint, IX_NPEMH_NPE_STAT_OFINT);

	/* if the OFINT status bit is set */
	if (ofint)
	{
	/* if there is an ISR registered for this NPE */
	if (ixNpeMhConfigNpeInfo[npeId].isr != NULL)
	{
	/* invoke the ISR routine */
	ixNpeMhConfigNpeInfo[npeId].isr (npeId);
	}
	else
	{
	/* if we don't service the interrupt the NPE will continue */
	/* to trigger the interrupt indefinitely */
	IX_NPEMH_ERROR_REPORT ("No ISR registered to service "
	"interrupt\n");
	}
	}

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
	"ixNpeMhConfigIsr\n");
	}

	/*
	* Function definition: ixNpeMhConfigInitialize
	*/

	void ixNpeMhConfigInitialize (
	IxNpeMhNpeInterrupts npeInterrupts)
	{
	IxNpeMhNpeId npeId;
	UINT32 virtualAddr[IX_NPEMH_NUM_NPES];

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
	"ixNpeMhConfigInitialize\n");

	/* Request a mapping for the NPE-A config register address space */
	virtualAddr[IX_NPEMH_NPEID_NPEA] =
	(UINT32) IX_OSAL_MEM_MAP (IX_NPEMH_NPEA_BASE,
	IX_OSAL_IXP400_NPEA_MAP_SIZE);
	IX_OSAL_ASSERT (virtualAddr[IX_NPEMH_NPEID_NPEA]);

	/* Request a mapping for the NPE-B config register address space */
	virtualAddr[IX_NPEMH_NPEID_NPEB] =
	(UINT32) IX_OSAL_MEM_MAP (IX_NPEMH_NPEB_BASE,
	IX_OSAL_IXP400_NPEB_MAP_SIZE);
	IX_OSAL_ASSERT (virtualAddr[IX_NPEMH_NPEID_NPEB]);

	/* Request a mapping for the NPE-C config register address space */
	virtualAddr[IX_NPEMH_NPEID_NPEC] =
	(UINT32) IX_OSAL_MEM_MAP (IX_NPEMH_NPEC_BASE,
	IX_OSAL_IXP400_NPEC_MAP_SIZE);
	IX_OSAL_ASSERT (virtualAddr[IX_NPEMH_NPEID_NPEC]);

	/* for each NPE ... */
	for (npeId = 0; npeId < IX_NPEMH_NUM_NPES; npeId++)
	{
	/* declare a convenience pointer */
	IxNpeMhConfigNpeInfo *npeInfo = &ixNpeMhConfigNpeInfo[npeId];

	/* store the virtual addresses of the NPE registers for later use */
	npeInfo->virtualRegisterBase = virtualAddr[npeId];
	npeInfo->statusRegister = virtualAddr[npeId] + IX_NPEMH_NPESTAT_OFFSET;
	npeInfo->controlRegister = virtualAddr[npeId] + IX_NPEMH_NPECTL_OFFSET;
	npeInfo->inFifoRegister = virtualAddr[npeId] + IX_NPEMH_NPEFIFO_OFFSET;
	npeInfo->outFifoRegister = virtualAddr[npeId] + IX_NPEMH_NPEFIFO_OFFSET;

	/* for test purposes - to verify the register addresses */
	IX_NPEMH_TRACE2 (IX_NPEMH_DEBUG, "NPE %d status register = "
	"0x%08X\n", npeId, npeInfo->statusRegister);
	IX_NPEMH_TRACE2 (IX_NPEMH_DEBUG, "NPE %d control register = "
	"0x%08X\n", npeId, npeInfo->controlRegister);
	IX_NPEMH_TRACE2 (IX_NPEMH_DEBUG, "NPE %d inFifo register = "
	"0x%08X\n", npeId, npeInfo->inFifoRegister);
	IX_NPEMH_TRACE2 (IX_NPEMH_DEBUG, "NPE %d outFifo register = "
	"0x%08X\n", npeId, npeInfo->outFifoRegister);

	/* connect our ISR to the NPE interrupt */
	(void) ixOsalIrqBind (
	npeInfo->interruptId, ixNpeMhConfigIsr, (void *)npeId);

	/* initialise a mutex for this NPE */
	(void) ixOsalMutexInit (&npeInfo->mutex);

	/* if we should service the NPE's "outFIFO not empty" interrupt */
	if (npeInterrupts == IX_NPEMH_NPEINTERRUPTS_YES)
	{
	/* enable the NPE's "outFIFO not empty" interrupt */
	ixNpeMhConfigNpeInterruptEnable (npeId);
	}
	else
	{
	/* disable the NPE's "outFIFO not empty" interrupt */
	ixNpeMhConfigNpeInterruptDisable (npeId);
	}
	}

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
	"ixNpeMhConfigInitialize\n");
	}

	/*
	* Function definition: ixNpeMhConfigUninit
	*/

	void ixNpeMhConfigUninit (void)
	{
	IxNpeMhNpeId npeId;

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
	"ixNpeMhConfigUninit\n");

	/* for each NPE ... */
	for (npeId = 0; npeId < IX_NPEMH_NUM_NPES; npeId++)
	{
	/* declare a convenience pointer */
	IxNpeMhConfigNpeInfo *npeInfo = &ixNpeMhConfigNpeInfo[npeId];

	/* disconnect ISR */
	ixOsalIrqUnbind(npeInfo->interruptId);

	/* destroy mutex associated with this NPE */
	ixOsalMutexDestroy(&npeInfo->mutex);

	IX_OSAL_MEM_UNMAP (npeInfo->virtualRegisterBase);

	npeInfo->virtualRegisterBase = 0;
	npeInfo->statusRegister = 0;
	npeInfo->controlRegister = 0;
	npeInfo->inFifoRegister = 0;
	npeInfo->outFifoRegister = 0;
	}

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
	"ixNpeMhConfigUninit\n");
	}

	/*
	* Function definition: ixNpeMhConfigIsrRegister
	*/

	void ixNpeMhConfigIsrRegister (
	IxNpeMhNpeId npeId,
	IxNpeMhConfigIsr isr)
	{
	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
	"ixNpeMhConfigIsrRegister\n");

	/* check if there is already an ISR registered for this NPE */
	if (ixNpeMhConfigNpeInfo[npeId].isr != NULL)
	{
	IX_NPEMH_TRACE0 (IX_NPEMH_DEBUG, "Over-writing registered NPE ISR\n");
	}

	/* save the ISR routine with the NPE info */
	ixNpeMhConfigNpeInfo[npeId].isr = isr;

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
	"ixNpeMhConfigIsrRegister\n");
	}

	/*
	* Function definition: ixNpeMhConfigNpeInterruptEnable
	*/

	BOOL ixNpeMhConfigNpeInterruptEnable (
	IxNpeMhNpeId npeId)
	{
	UINT32 ofe;
	volatile UINT32 *controlReg =
	(UINT32 *)ixNpeMhConfigNpeInfo[npeId].controlRegister;

	/* get the OFE (OutFifoEnable) bit of the control register */
	IX_NPEMH_REGISTER_READ_BITS (controlReg, &ofe, IX_NPEMH_NPE_CTL_OFE);

	/* if the interrupt is disabled then we must enable it */
	if (!ofe)
	{
	/* set the OFE (OutFifoEnable) bit of the control register */
	/* we must set the OFEWE (OutFifoEnableWriteEnable) at the same */
	/* time for the write to have effect */
	IX_NPEMH_REGISTER_WRITE_BITS (controlReg,
	(IX_NPEMH_NPE_CTL_OFE \|
	IX_NPEMH_NPE_CTL_OFEWE),
	(IX_NPEMH_NPE_CTL_OFE \|
	IX_NPEMH_NPE_CTL_OFEWE));
	}

	/* return the previous state of the interrupt */
	return (ofe != 0);
	}

	/*
	* Function definition: ixNpeMhConfigNpeInterruptDisable
	*/

	BOOL ixNpeMhConfigNpeInterruptDisable (
	IxNpeMhNpeId npeId)
	{
	UINT32 ofe;
	volatile UINT32 *controlReg =
	(UINT32 *)ixNpeMhConfigNpeInfo[npeId].controlRegister;

	/* get the OFE (OutFifoEnable) bit of the control register */
	IX_NPEMH_REGISTER_READ_BITS (controlReg, &ofe, IX_NPEMH_NPE_CTL_OFE);

	/* if the interrupt is enabled then we must disable it */
	if (ofe)
	{
	/* unset the OFE (OutFifoEnable) bit of the control register */
	/* we must set the OFEWE (OutFifoEnableWriteEnable) at the same */
	/* time for the write to have effect */
	IX_NPEMH_REGISTER_WRITE_BITS (controlReg,
	(0 \|
	IX_NPEMH_NPE_CTL_OFEWE),
	(IX_NPEMH_NPE_CTL_OFE \|
	IX_NPEMH_NPE_CTL_OFEWE));
	}

	/* return the previous state of the interrupt */
	return (ofe != 0);
	}

	/*
	* Function definition: ixNpeMhConfigMessageIdGet
	*/

	IxNpeMhMessageId ixNpeMhConfigMessageIdGet (
	IxNpeMhMessage message)
	{
	/* return the most-significant byte of the first word of the */
	/* message */
	return ((IxNpeMhMessageId) ((message.data[0] >> 24) & 0xFF));
	}

	/*
	* Function definition: ixNpeMhConfigNpeIdIsValid
	*/

	BOOL ixNpeMhConfigNpeIdIsValid (
	IxNpeMhNpeId npeId)
	{
	/* check that the npeId parameter is within the range of valid IDs */
	return (npeId >= 0 && npeId < IX_NPEMH_NUM_NPES);
	}

	/*
	* Function definition: ixNpeMhConfigLockGet
	*/

	void ixNpeMhConfigLockGet (
	IxNpeMhNpeId npeId)
	{
	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
	"ixNpeMhConfigLockGet\n");

	/* lock the mutex for this NPE */
	(void) ixOsalMutexLock (&ixNpeMhConfigNpeInfo[npeId].mutex,
	IX_OSAL_WAIT_FOREVER);

	/* disable the NPE's "outFIFO not empty" interrupt */
	ixNpeMhConfigNpeInfo[npeId].oldInterruptState =
	ixNpeMhConfigNpeInterruptDisable (npeId);

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
	"ixNpeMhConfigLockGet\n");
	}

	/*
	* Function definition: ixNpeMhConfigLockRelease
	*/

	void ixNpeMhConfigLockRelease (
	IxNpeMhNpeId npeId)
	{
	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Entering "
	"ixNpeMhConfigLockRelease\n");

	/* if the interrupt was previously enabled */
	if (ixNpeMhConfigNpeInfo[npeId].oldInterruptState)
	{
	/* enable the NPE's "outFIFO not empty" interrupt */
	ixNpeMhConfigNpeInfo[npeId].oldInterruptState =
	ixNpeMhConfigNpeInterruptEnable (npeId);
	}

	/* unlock the mutex for this NPE */
	(void) ixOsalMutexUnlock (&ixNpeMhConfigNpeInfo[npeId].mutex);

	IX_NPEMH_TRACE0 (IX_NPEMH_FN_ENTRY_EXIT, "Exiting "
	"ixNpeMhConfigLockRelease\n");
	}

	/*
	* Function definition: ixNpeMhConfigInFifoWrite
	*/

	IX_STATUS ixNpeMhConfigInFifoWrite (
	IxNpeMhNpeId npeId,
	IxNpeMhMessage message)
	{
	volatile UINT32 *npeInFifo =
	(UINT32 *)ixNpeMhConfigNpeInfo[npeId].inFifoRegister;
	UINT32 retriesCount = 0;

	/* write the first word of the message to the NPE's inFIFO */
	IX_NPEMH_REGISTER_WRITE (npeInFifo, message.data[0]);

	/* need to wait for room to write second word - see SCR #493,
	poll for maximum number of retries, if exceed maximum
	retries, exit from while loop */
	while ((IX_NPE_MH_MAX_NUM_OF_RETRIES > retriesCount)
	&& ixNpeMhConfigInFifoIsFull (npeId))
	{
	retriesCount++;
	}

	/* Return TIMEOUT status to caller, indicate that NPE Hang / Halt */
	if (IX_NPE_MH_MAX_NUM_OF_RETRIES == retriesCount)
	{
	return IX_NPEMH_CRITICAL_NPE_ERR;
	}

	/* write the second word of the message to the NPE's inFIFO */
	IX_NPEMH_REGISTER_WRITE (npeInFifo, message.data[1]);

	/* record in the stats the maximum number of retries needed */
	if (ixNpeMhConfigStats[npeId].maxInFifoFullRetries < retriesCount)
	{
	ixNpeMhConfigStats[npeId].maxInFifoFullRetries = retriesCount;
	}

	/* update statistical info */
	ixNpeMhConfigStats[npeId].inFifoWrites++;

	return IX_SUCCESS;
	}

	/*
	* Function definition: ixNpeMhConfigOutFifoRead
	*/

	IX_STATUS ixNpeMhConfigOutFifoRead (
	IxNpeMhNpeId npeId,
	IxNpeMhMessage *message)
	{
	volatile UINT32 *npeOutFifo =
	(UINT32 *)ixNpeMhConfigNpeInfo[npeId].outFifoRegister;
	UINT32 retriesCount = 0;

	/* read the first word of the message from the NPE's outFIFO */
	IX_NPEMH_REGISTER_READ (npeOutFifo, &message->data[0]);

	/* need to wait for NPE to write second word - see SCR #493
	poll for maximum number of retries, if exceed maximum
	retries, exit from while loop */
	while ((IX_NPE_MH_MAX_NUM_OF_RETRIES > retriesCount)
	&& ixNpeMhConfigOutFifoIsEmpty (npeId))
	{
	retriesCount++;
	}

	/* Return TIMEOUT status to caller, indicate that NPE Hang / Halt */
	if (IX_NPE_MH_MAX_NUM_OF_RETRIES == retriesCount)
	{
	return IX_NPEMH_CRITICAL_NPE_ERR;
	}

	/* read the second word of the message from the NPE's outFIFO */
	IX_NPEMH_REGISTER_READ (npeOutFifo, &message->data[1]);

	/* record in the stats the maximum number of retries needed */
	if (ixNpeMhConfigStats[npeId].maxOutFifoEmptyRetries < retriesCount)
	{
	ixNpeMhConfigStats[npeId].maxOutFifoEmptyRetries = retriesCount;
	}

	/* update statistical info */
	ixNpeMhConfigStats[npeId].outFifoReads++;

	return IX_SUCCESS;
	}

	/*
	* Function definition: ixNpeMhConfigShow
	*/

	void ixNpeMhConfigShow (
	IxNpeMhNpeId npeId)
	{
	/* show the message fifo read counter */
	IX_NPEMH_SHOW ("Message FIFO reads",
	ixNpeMhConfigStats[npeId].outFifoReads);

	/* show the message fifo write counter */
	IX_NPEMH_SHOW ("Message FIFO writes",
	ixNpeMhConfigStats[npeId].inFifoWrites);

	/* show the max retries performed when inFIFO full */
	IX_NPEMH_SHOW ("Max inFIFO Full retries",
	ixNpeMhConfigStats[npeId].maxInFifoFullRetries);

	/* show the max retries performed when outFIFO empty */
	IX_NPEMH_SHOW ("Max outFIFO Empty retries",
	ixNpeMhConfigStats[npeId].maxOutFifoEmptyRetries);

	/* show the current status of the inFifo */
	ixOsalLog (IX_OSAL_LOG_LVL_USER, IX_OSAL_LOG_DEV_STDOUT,
	"InFifo is %s and %s\n",
	(ixNpeMhConfigInFifoIsEmpty (npeId) ?
	(int) "EMPTY" : (int) "NOT EMPTY"),
	(ixNpeMhConfigInFifoIsFull (npeId) ?
	(int) "FULL" : (int) "NOT FULL"),
	0, 0, 0, 0);

	/* show the current status of the outFifo */
	ixOsalLog (IX_OSAL_LOG_LVL_USER, IX_OSAL_LOG_DEV_STDOUT,
	"OutFifo is %s and %s\n",
	(ixNpeMhConfigOutFifoIsEmpty (npeId) ?
	(int) "EMPTY" : (int) "NOT EMPTY"),
	(ixNpeMhConfigOutFifoIsFull (npeId) ?
	(int) "FULL" : (int) "NOT FULL"),
	0, 0, 0, 0);
	}

	/*
	* Function definition: ixNpeMhConfigShowReset
	*/

	void ixNpeMhConfigShowReset (
	IxNpeMhNpeId npeId)
	{
	/* reset the message fifo read counter */
	ixNpeMhConfigStats[npeId].outFifoReads = 0;

	/* reset the message fifo write counter */
	ixNpeMhConfigStats[npeId].inFifoWrites = 0;

	/* reset the max inFIFO Full retries counter */
	ixNpeMhConfigStats[npeId].maxInFifoFullRetries = 0;

	/* reset the max outFIFO empty retries counter */
	ixNpeMhConfigStats[npeId].maxOutFifoEmptyRetries = 0;
	}