upstream u-boot with additional patches for our devices/boards: https://lists.denx.de/pipermail/u-boot/2017-March/282789.html (AXP crashes) ; Gbit ethernet patch for some LIME2 revisions ; with SPI flash support
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u-boot/drivers/net/npe/IxNpeDlNpeMgrUtils.c

782 lines
22 KiB

/**
* @file IxNpeDlNpeMgrUtils.c
*
* @author Intel Corporation
* @date 18 February 2002
*
* @brief This file contains the implementation of the private API for the
* IXP425 NPE Downloader NpeMgr Utils module
*
*
* @par
* IXP400 SW Release version 2.0
*
* -- Copyright Notice --
*
* @par
* Copyright 2001-2005, Intel Corporation.
* All rights reserved.
*
* @par
* SPDX-License-Identifier: BSD-3-Clause
* @par
* -- End of Copyright Notice --
*/
/*
* Put the system defined include files required.
*/
#define IX_NPE_DL_MAX_NUM_OF_RETRIES 1000000 /**< Maximum number of
* retries before
* timeout
*/
/*
* Put the user defined include files required.
*/
#include "IxOsal.h"
#include "IxNpeDl.h"
#include "IxNpeDlNpeMgrUtils_p.h"
#include "IxNpeDlNpeMgrEcRegisters_p.h"
#include "IxNpeDlMacros_p.h"
/*
* #defines and macros used in this file.
*/
/* used to bit-mask a number of bytes */
#define IX_NPEDL_MASK_LOWER_BYTE_OF_WORD 0x000000FF
#define IX_NPEDL_MASK_LOWER_SHORT_OF_WORD 0x0000FFFF
#define IX_NPEDL_MASK_FULL_WORD 0xFFFFFFFF
#define IX_NPEDL_BYTES_PER_WORD 4
#define IX_NPEDL_BYTES_PER_SHORT 2
#define IX_NPEDL_REG_SIZE_BYTE 8
#define IX_NPEDL_REG_SIZE_SHORT 16
#define IX_NPEDL_REG_SIZE_WORD 32
/*
* Introduce extra read cycles after issuing read command to NPE
* so that we read the register after the NPE has updated it
* This is to overcome race condition between XScale and NPE
*/
#define IX_NPEDL_DELAY_READ_CYCLES 2
/*
* To mask top three MSBs of 32bit word to download into NPE IMEM
*/
#define IX_NPEDL_MASK_UNUSED_IMEM_BITS 0x1FFFFFFF;
/*
* typedefs
*/
typedef struct
{
UINT32 regAddress;
UINT32 regSize;
} IxNpeDlCtxtRegAccessInfo;
/* module statistics counters */
typedef struct
{
UINT32 insMemWrites;
UINT32 insMemWriteFails;
UINT32 dataMemWrites;
UINT32 dataMemWriteFails;
UINT32 ecsRegWrites;
UINT32 ecsRegReads;
UINT32 dbgInstructionExecs;
UINT32 contextRegWrites;
UINT32 physicalRegWrites;
UINT32 nextPcWrites;
} IxNpeDlNpeMgrUtilsStats;
/*
* Variable declarations global to this file only. Externs are followed by
* static variables.
*/
/*
* contains useful address and function pointers to read/write Context Regs,
* eliminating some switch or if-else statements in places
*/
static IxNpeDlCtxtRegAccessInfo ixNpeDlCtxtRegAccInfo[IX_NPEDL_CTXT_REG_MAX] =
{
{
IX_NPEDL_CTXT_REG_ADDR_STEVT,
IX_NPEDL_REG_SIZE_BYTE
},
{
IX_NPEDL_CTXT_REG_ADDR_STARTPC,
IX_NPEDL_REG_SIZE_SHORT
},
{
IX_NPEDL_CTXT_REG_ADDR_REGMAP,
IX_NPEDL_REG_SIZE_SHORT
},
{
IX_NPEDL_CTXT_REG_ADDR_CINDEX,
IX_NPEDL_REG_SIZE_BYTE
}
};
static UINT32 ixNpeDlSavedExecCount = 0;
static UINT32 ixNpeDlSavedEcsDbgCtxtReg2 = 0;
static IxNpeDlNpeMgrUtilsStats ixNpeDlNpeMgrUtilsStats;
/*
* static function prototypes.
*/
PRIVATE __inline__ void
ixNpeDlNpeMgrWriteCommandIssue (UINT32 npeBaseAddress, UINT32 cmd,
UINT32 addr, UINT32 data);
PRIVATE __inline__ UINT32
ixNpeDlNpeMgrReadCommandIssue (UINT32 npeBaseAddress, UINT32 cmd, UINT32 addr);
PRIVATE IX_STATUS
ixNpeDlNpeMgrLogicalRegRead (UINT32 npeBaseAddress, UINT32 regAddr,
UINT32 regSize, UINT32 ctxtNum, UINT32 *regVal);
PRIVATE IX_STATUS
ixNpeDlNpeMgrLogicalRegWrite (UINT32 npeBaseAddress, UINT32 regAddr,
UINT32 regVal, UINT32 regSize,
UINT32 ctxtNum, BOOL verify);
/*
* Function definition: ixNpeDlNpeMgrWriteCommandIssue
*/
PRIVATE __inline__ void
ixNpeDlNpeMgrWriteCommandIssue (
UINT32 npeBaseAddress,
UINT32 cmd,
UINT32 addr,
UINT32 data)
{
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXDATA, data);
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXAD, addr);
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXCTL, cmd);
}
/*
* Function definition: ixNpeDlNpeMgrReadCommandIssue
*/
PRIVATE __inline__ UINT32
ixNpeDlNpeMgrReadCommandIssue (
UINT32 npeBaseAddress,
UINT32 cmd,
UINT32 addr)
{
UINT32 data = 0;
int i;
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXAD, addr);
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXCTL, cmd);
for (i = 0; i <= IX_NPEDL_DELAY_READ_CYCLES; i++)
{
IX_NPEDL_REG_READ (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXDATA, &data);
}
return data;
}
/*
* Function definition: ixNpeDlNpeMgrInsMemWrite
*/
IX_STATUS
ixNpeDlNpeMgrInsMemWrite (
UINT32 npeBaseAddress,
UINT32 insMemAddress,
UINT32 insMemData,
BOOL verify)
{
UINT32 insMemDataRtn;
ixNpeDlNpeMgrWriteCommandIssue (npeBaseAddress,
IX_NPEDL_EXCTL_CMD_WR_INS_MEM,
insMemAddress, insMemData);
if (verify)
{
/* write invalid data to this reg, so we can see if we're reading
the EXDATA register too early */
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXDATA,
~insMemData);
/*Disabled since top 3 MSB are not used for Azusa hardware Refer WR:IXA00053900*/
insMemData&=IX_NPEDL_MASK_UNUSED_IMEM_BITS;
insMemDataRtn=ixNpeDlNpeMgrReadCommandIssue (npeBaseAddress,
IX_NPEDL_EXCTL_CMD_RD_INS_MEM,
insMemAddress);
insMemDataRtn&=IX_NPEDL_MASK_UNUSED_IMEM_BITS;
if (insMemData != insMemDataRtn)
{
ixNpeDlNpeMgrUtilsStats.insMemWriteFails++;
return IX_FAIL;
}
}
ixNpeDlNpeMgrUtilsStats.insMemWrites++;
return IX_SUCCESS;
}
/*
* Function definition: ixNpeDlNpeMgrDataMemWrite
*/
IX_STATUS
ixNpeDlNpeMgrDataMemWrite (
UINT32 npeBaseAddress,
UINT32 dataMemAddress,
UINT32 dataMemData,
BOOL verify)
{
ixNpeDlNpeMgrWriteCommandIssue (npeBaseAddress,
IX_NPEDL_EXCTL_CMD_WR_DATA_MEM,
dataMemAddress, dataMemData);
if (verify)
{
/* write invalid data to this reg, so we can see if we're reading
the EXDATA register too early */
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXDATA, ~dataMemData);
if (dataMemData !=
ixNpeDlNpeMgrReadCommandIssue (npeBaseAddress,
IX_NPEDL_EXCTL_CMD_RD_DATA_MEM,
dataMemAddress))
{
ixNpeDlNpeMgrUtilsStats.dataMemWriteFails++;
return IX_FAIL;
}
}
ixNpeDlNpeMgrUtilsStats.dataMemWrites++;
return IX_SUCCESS;
}
/*
* Function definition: ixNpeDlNpeMgrExecAccRegWrite
*/
void
ixNpeDlNpeMgrExecAccRegWrite (
UINT32 npeBaseAddress,
UINT32 regAddress,
UINT32 regData)
{
ixNpeDlNpeMgrWriteCommandIssue (npeBaseAddress,
IX_NPEDL_EXCTL_CMD_WR_ECS_REG,
regAddress, regData);
ixNpeDlNpeMgrUtilsStats.ecsRegWrites++;
}
/*
* Function definition: ixNpeDlNpeMgrExecAccRegRead
*/
UINT32
ixNpeDlNpeMgrExecAccRegRead (
UINT32 npeBaseAddress,
UINT32 regAddress)
{
ixNpeDlNpeMgrUtilsStats.ecsRegReads++;
return ixNpeDlNpeMgrReadCommandIssue (npeBaseAddress,
IX_NPEDL_EXCTL_CMD_RD_ECS_REG,
regAddress);
}
/*
* Function definition: ixNpeDlNpeMgrCommandIssue
*/
void
ixNpeDlNpeMgrCommandIssue (
UINT32 npeBaseAddress,
UINT32 command)
{
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Entering ixNpeDlNpeMgrCommandIssue\n");
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXCTL, command);
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Exiting ixNpeDlNpeMgrCommandIssue\n");
}
/*
* Function definition: ixNpeDlNpeMgrDebugInstructionPreExec
*/
void
ixNpeDlNpeMgrDebugInstructionPreExec(
UINT32 npeBaseAddress)
{
/* turn off the halt bit by clearing Execution Count register. */
/* save reg contents 1st and restore later */
IX_NPEDL_REG_READ (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXCT,
&ixNpeDlSavedExecCount);
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXCT, 0);
/* ensure that IF and IE are on (temporarily), so that we don't end up
* stepping forever */
ixNpeDlSavedEcsDbgCtxtReg2 = ixNpeDlNpeMgrExecAccRegRead (npeBaseAddress,
IX_NPEDL_ECS_DBG_CTXT_REG_2);
ixNpeDlNpeMgrExecAccRegWrite (npeBaseAddress, IX_NPEDL_ECS_DBG_CTXT_REG_2,
(ixNpeDlSavedEcsDbgCtxtReg2 |
IX_NPEDL_MASK_ECS_DBG_REG_2_IF |
IX_NPEDL_MASK_ECS_DBG_REG_2_IE));
}
/*
* Function definition: ixNpeDlNpeMgrDebugInstructionExec
*/
IX_STATUS
ixNpeDlNpeMgrDebugInstructionExec(
UINT32 npeBaseAddress,
UINT32 npeInstruction,
UINT32 ctxtNum,
UINT32 ldur)
{
UINT32 ecsDbgRegVal;
UINT32 oldWatchcount, newWatchcount;
UINT32 retriesCount = 0;
IX_STATUS status = IX_SUCCESS;
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Entering ixNpeDlNpeMgrDebugInstructionExec\n");
/* set the Active bit, and the LDUR, in the debug level */
ecsDbgRegVal = IX_NPEDL_MASK_ECS_REG_0_ACTIVE |
(ldur << IX_NPEDL_OFFSET_ECS_REG_0_LDUR);
ixNpeDlNpeMgrExecAccRegWrite (npeBaseAddress, IX_NPEDL_ECS_DBG_CTXT_REG_0,
ecsDbgRegVal);
/*
* set CCTXT at ECS DEBUG L3 to specify in which context to execute the
* instruction, and set SELCTXT at ECS DEBUG Level to specify which context
* store to access.
* Debug ECS Level Reg 1 has form 0x000n000n, where n = context number
*/
ecsDbgRegVal = (ctxtNum << IX_NPEDL_OFFSET_ECS_REG_1_CCTXT) |
(ctxtNum << IX_NPEDL_OFFSET_ECS_REG_1_SELCTXT);
ixNpeDlNpeMgrExecAccRegWrite (npeBaseAddress, IX_NPEDL_ECS_DBG_CTXT_REG_1,
ecsDbgRegVal);
/* clear the pipeline */
ixNpeDlNpeMgrCommandIssue (npeBaseAddress, IX_NPEDL_EXCTL_CMD_NPE_CLR_PIPE);
/* load NPE instruction into the instruction register */
ixNpeDlNpeMgrExecAccRegWrite (npeBaseAddress, IX_NPEDL_ECS_INSTRUCT_REG,
npeInstruction);
/* we need this value later to wait for completion of NPE execution step */
IX_NPEDL_REG_READ (npeBaseAddress, IX_NPEDL_REG_OFFSET_WC, &oldWatchcount);
/* issue a Step One command via the Execution Control register */
ixNpeDlNpeMgrCommandIssue (npeBaseAddress, IX_NPEDL_EXCTL_CMD_NPE_STEP);
/* Watch Count register increments when NPE completes an instruction */
IX_NPEDL_REG_READ (npeBaseAddress, IX_NPEDL_REG_OFFSET_WC,
&newWatchcount);
/*
* force the XScale to wait until the NPE has finished execution step
* NOTE that this delay will be very small, just long enough to allow a
* single NPE instruction to complete execution; if instruction execution
* is not completed before timeout retries, exit the while loop
*/
while ((IX_NPE_DL_MAX_NUM_OF_RETRIES > retriesCount)
&& (newWatchcount == oldWatchcount))
{
/* Watch Count register increments when NPE completes an instruction */
IX_NPEDL_REG_READ (npeBaseAddress, IX_NPEDL_REG_OFFSET_WC,
&newWatchcount);
retriesCount++;
}
if (IX_NPE_DL_MAX_NUM_OF_RETRIES > retriesCount)
{
ixNpeDlNpeMgrUtilsStats.dbgInstructionExecs++;
}
else
{
/* Return timeout status as the instruction has not been executed
* after maximum retries */
status = IX_NPEDL_CRITICAL_NPE_ERR;
}
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Exiting ixNpeDlNpeMgrDebugInstructionExec\n");
return status;
}
/*
* Function definition: ixNpeDlNpeMgrDebugInstructionPostExec
*/
void
ixNpeDlNpeMgrDebugInstructionPostExec(
UINT32 npeBaseAddress)
{
/* clear active bit in debug level */
ixNpeDlNpeMgrExecAccRegWrite (npeBaseAddress, IX_NPEDL_ECS_DBG_CTXT_REG_0,
0);
/* clear the pipeline */
ixNpeDlNpeMgrCommandIssue (npeBaseAddress, IX_NPEDL_EXCTL_CMD_NPE_CLR_PIPE);
/* restore Execution Count register contents. */
IX_NPEDL_REG_WRITE (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXCT,
ixNpeDlSavedExecCount);
/* restore IF and IE bits to original values */
ixNpeDlNpeMgrExecAccRegWrite (npeBaseAddress, IX_NPEDL_ECS_DBG_CTXT_REG_2,
ixNpeDlSavedEcsDbgCtxtReg2);
}
/*
* Function definition: ixNpeDlNpeMgrLogicalRegRead
*/
PRIVATE IX_STATUS
ixNpeDlNpeMgrLogicalRegRead (
UINT32 npeBaseAddress,
UINT32 regAddr,
UINT32 regSize,
UINT32 ctxtNum,
UINT32 *regVal)
{
IX_STATUS status = IX_SUCCESS;
UINT32 npeInstruction = 0;
UINT32 mask = 0;
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Entering ixNpeDlNpeMgrLogicalRegRead\n");
switch (regSize)
{
case IX_NPEDL_REG_SIZE_BYTE:
npeInstruction = IX_NPEDL_INSTR_RD_REG_BYTE;
mask = IX_NPEDL_MASK_LOWER_BYTE_OF_WORD; break;
case IX_NPEDL_REG_SIZE_SHORT:
npeInstruction = IX_NPEDL_INSTR_RD_REG_SHORT;
mask = IX_NPEDL_MASK_LOWER_SHORT_OF_WORD; break;
case IX_NPEDL_REG_SIZE_WORD:
npeInstruction = IX_NPEDL_INSTR_RD_REG_WORD;
mask = IX_NPEDL_MASK_FULL_WORD; break;
}
/* make regAddr be the SRC and DEST operands (e.g. movX d0, d0) */
npeInstruction |= (regAddr << IX_NPEDL_OFFSET_INSTR_SRC) |
(regAddr << IX_NPEDL_OFFSET_INSTR_DEST);
/* step execution of NPE intruction using Debug Executing Context stack */
status = ixNpeDlNpeMgrDebugInstructionExec (npeBaseAddress, npeInstruction,
ctxtNum, IX_NPEDL_RD_INSTR_LDUR);
if (IX_SUCCESS != status)
{
return status;
}
/* read value of register from Execution Data register */
IX_NPEDL_REG_READ (npeBaseAddress, IX_NPEDL_REG_OFFSET_EXDATA, regVal);
/* align value from left to right */
*regVal = (*regVal >> (IX_NPEDL_REG_SIZE_WORD - regSize)) & mask;
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Exiting ixNpeDlNpeMgrLogicalRegRead\n");
return IX_SUCCESS;
}
/*
* Function definition: ixNpeDlNpeMgrLogicalRegWrite
*/
PRIVATE IX_STATUS
ixNpeDlNpeMgrLogicalRegWrite (
UINT32 npeBaseAddress,
UINT32 regAddr,
UINT32 regVal,
UINT32 regSize,
UINT32 ctxtNum,
BOOL verify)
{
UINT32 npeInstruction = 0;
UINT32 mask = 0;
IX_STATUS status = IX_SUCCESS;
UINT32 retRegVal;
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Entering ixNpeDlNpeMgrLogicalRegWrite\n");
if (regSize == IX_NPEDL_REG_SIZE_WORD)
{
/* NPE register addressing is left-to-right: e.g. |d0|d1|d2|d3| */
/* Write upper half-word (short) to |d0|d1| */
status = ixNpeDlNpeMgrLogicalRegWrite (npeBaseAddress, regAddr,
regVal >> IX_NPEDL_REG_SIZE_SHORT,
IX_NPEDL_REG_SIZE_SHORT,
ctxtNum, verify);
if (IX_SUCCESS != status)
{
return status;
}
/* Write lower half-word (short) to |d2|d3| */
status = ixNpeDlNpeMgrLogicalRegWrite (npeBaseAddress,
regAddr + IX_NPEDL_BYTES_PER_SHORT,
regVal & IX_NPEDL_MASK_LOWER_SHORT_OF_WORD,
IX_NPEDL_REG_SIZE_SHORT,
ctxtNum, verify);
if (IX_SUCCESS != status)
{
return status;
}
}
else
{
switch (regSize)
{
case IX_NPEDL_REG_SIZE_BYTE:
npeInstruction = IX_NPEDL_INSTR_WR_REG_BYTE;
mask = IX_NPEDL_MASK_LOWER_BYTE_OF_WORD; break;
case IX_NPEDL_REG_SIZE_SHORT:
npeInstruction = IX_NPEDL_INSTR_WR_REG_SHORT;
mask = IX_NPEDL_MASK_LOWER_SHORT_OF_WORD; break;
}
/* mask out any redundant bits, so verify will work later */
regVal &= mask;
/* fill dest operand field of instruction with destination reg addr */
npeInstruction |= (regAddr << IX_NPEDL_OFFSET_INSTR_DEST);
/* fill src operand field of instruction with least-sig 5 bits of val*/
npeInstruction |= ((regVal & IX_NPEDL_MASK_IMMED_INSTR_SRC_DATA) <<
IX_NPEDL_OFFSET_INSTR_SRC);
/* fill coprocessor field of instruction with most-sig 11 bits of val*/
npeInstruction |= ((regVal & IX_NPEDL_MASK_IMMED_INSTR_COPROC_DATA) <<
IX_NPEDL_DISPLACE_IMMED_INSTR_COPROC_DATA);
/* step execution of NPE intruction using Debug ECS */
status = ixNpeDlNpeMgrDebugInstructionExec(npeBaseAddress, npeInstruction,
ctxtNum, IX_NPEDL_WR_INSTR_LDUR);
if (IX_SUCCESS != status)
{
return status;
}
}/* condition: if reg to be written is 8-bit or 16-bit (not 32-bit) */
if (verify)
{
status = ixNpeDlNpeMgrLogicalRegRead (npeBaseAddress, regAddr,
regSize, ctxtNum, &retRegVal);
if (IX_SUCCESS == status)
{
if (regVal != retRegVal)
{
status = IX_FAIL;
}
}
}
IX_NPEDL_TRACE1 (IX_NPEDL_FN_ENTRY_EXIT,
"Exiting ixNpeDlNpeMgrLogicalRegWrite : status = %d\n",
status);
return status;
}
/*
* Function definition: ixNpeDlNpeMgrPhysicalRegWrite
*/
IX_STATUS
ixNpeDlNpeMgrPhysicalRegWrite (
UINT32 npeBaseAddress,
UINT32 regAddr,
UINT32 regValue,
BOOL verify)
{
IX_STATUS status;
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Entering ixNpeDlNpeMgrPhysicalRegWrite\n");
/*
* There are 32 physical registers used in an NPE. These are
* treated as 16 pairs of 32-bit registers. To write one of the pair,
* write the pair number (0-16) to the REGMAP for Context 0. Then write
* the value to register 0 or 4 in the regfile, depending on which
* register of the pair is to be written
*/
/*
* set REGMAP for context 0 to (regAddr >> 1) to choose which pair (0-16)
* of physical registers to write
*/
status = ixNpeDlNpeMgrLogicalRegWrite (npeBaseAddress,
IX_NPEDL_CTXT_REG_ADDR_REGMAP,
(regAddr >>
IX_NPEDL_OFFSET_PHYS_REG_ADDR_REGMAP),
IX_NPEDL_REG_SIZE_SHORT, 0, verify);
if (status == IX_SUCCESS)
{
/* regAddr = 0 or 4 */
regAddr = (regAddr & IX_NPEDL_MASK_PHYS_REG_ADDR_LOGICAL_ADDR) *
IX_NPEDL_BYTES_PER_WORD;
status = ixNpeDlNpeMgrLogicalRegWrite (npeBaseAddress, regAddr, regValue,
IX_NPEDL_REG_SIZE_WORD, 0, verify);
}
if (status != IX_SUCCESS)
{
IX_NPEDL_ERROR_REPORT ("ixNpeDlNpeMgrPhysicalRegWrite: "
"error writing to physical register\n");
}
ixNpeDlNpeMgrUtilsStats.physicalRegWrites++;
IX_NPEDL_TRACE1 (IX_NPEDL_FN_ENTRY_EXIT,
"Exiting ixNpeDlNpeMgrPhysicalRegWrite : status = %d\n",
status);
return status;
}
/*
* Function definition: ixNpeDlNpeMgrCtxtRegWrite
*/
IX_STATUS
ixNpeDlNpeMgrCtxtRegWrite (
UINT32 npeBaseAddress,
UINT32 ctxtNum,
IxNpeDlCtxtRegNum ctxtReg,
UINT32 ctxtRegVal,
BOOL verify)
{
UINT32 tempRegVal;
UINT32 ctxtRegAddr;
UINT32 ctxtRegSize;
IX_STATUS status = IX_SUCCESS;
IX_NPEDL_TRACE0 (IX_NPEDL_FN_ENTRY_EXIT,
"Entering ixNpeDlNpeMgrCtxtRegWrite\n");
/*
* Context 0 has no STARTPC. Instead, this value is used to set
* NextPC for Background ECS, to set where NPE starts executing code
*/
if ((ctxtNum == 0) && (ctxtReg == IX_NPEDL_CTXT_REG_STARTPC))
{
/* read BG_CTXT_REG_0, update NEXTPC bits, and write back to reg */
tempRegVal = ixNpeDlNpeMgrExecAccRegRead (npeBaseAddress,
IX_NPEDL_ECS_BG_CTXT_REG_0);
tempRegVal &= ~IX_NPEDL_MASK_ECS_REG_0_NEXTPC;
tempRegVal |= (ctxtRegVal << IX_NPEDL_OFFSET_ECS_REG_0_NEXTPC) &
IX_NPEDL_MASK_ECS_REG_0_NEXTPC;
ixNpeDlNpeMgrExecAccRegWrite (npeBaseAddress,
IX_NPEDL_ECS_BG_CTXT_REG_0, tempRegVal);
ixNpeDlNpeMgrUtilsStats.nextPcWrites++;
}
else
{
ctxtRegAddr = ixNpeDlCtxtRegAccInfo[ctxtReg].regAddress;
ctxtRegSize = ixNpeDlCtxtRegAccInfo[ctxtReg].regSize;
status = ixNpeDlNpeMgrLogicalRegWrite (npeBaseAddress, ctxtRegAddr,
ctxtRegVal, ctxtRegSize,
ctxtNum, verify);
if (status != IX_SUCCESS)
{
IX_NPEDL_ERROR_REPORT ("ixNpeDlNpeMgrCtxtRegWrite: "
"error writing to context store register\n");
}
ixNpeDlNpeMgrUtilsStats.contextRegWrites++;
}
IX_NPEDL_TRACE1 (IX_NPEDL_FN_ENTRY_EXIT,
"Exiting ixNpeDlNpeMgrCtxtRegWrite : status = %d\n",
status);
return status;
}
/*
* Function definition: ixNpeDlNpeMgrUtilsStatsShow
*/
void
ixNpeDlNpeMgrUtilsStatsShow (void)
{
ixOsalLog (IX_OSAL_LOG_LVL_USER,
IX_OSAL_LOG_DEV_STDOUT,
"\nixNpeDlNpeMgrUtilsStatsShow:\n"
"\tInstruction Memory writes: %u\n"
"\tInstruction Memory writes failed: %u\n"
"\tData Memory writes: %u\n"
"\tData Memory writes failed: %u\n",
ixNpeDlNpeMgrUtilsStats.insMemWrites,
ixNpeDlNpeMgrUtilsStats.insMemWriteFails,
ixNpeDlNpeMgrUtilsStats.dataMemWrites,
ixNpeDlNpeMgrUtilsStats.dataMemWriteFails,
0,0);
ixOsalLog (IX_OSAL_LOG_LVL_USER,
IX_OSAL_LOG_DEV_STDOUT,
"\tExecuting Context Stack Register writes: %u\n"
"\tExecuting Context Stack Register reads: %u\n"
"\tPhysical Register writes: %u\n"
"\tContext Store Register writes: %u\n"
"\tExecution Backgound Context NextPC writes: %u\n"
"\tDebug Instructions Executed: %u\n\n",
ixNpeDlNpeMgrUtilsStats.ecsRegWrites,
ixNpeDlNpeMgrUtilsStats.ecsRegReads,
ixNpeDlNpeMgrUtilsStats.physicalRegWrites,
ixNpeDlNpeMgrUtilsStats.contextRegWrites,
ixNpeDlNpeMgrUtilsStats.nextPcWrites,
ixNpeDlNpeMgrUtilsStats.dbgInstructionExecs);
}
/*
* Function definition: ixNpeDlNpeMgrUtilsStatsReset
*/
void
ixNpeDlNpeMgrUtilsStatsReset (void)
{
ixNpeDlNpeMgrUtilsStats.insMemWrites = 0;
ixNpeDlNpeMgrUtilsStats.insMemWriteFails = 0;
ixNpeDlNpeMgrUtilsStats.dataMemWrites = 0;
ixNpeDlNpeMgrUtilsStats.dataMemWriteFails = 0;
ixNpeDlNpeMgrUtilsStats.ecsRegWrites = 0;
ixNpeDlNpeMgrUtilsStats.ecsRegReads = 0;
ixNpeDlNpeMgrUtilsStats.physicalRegWrites = 0;
ixNpeDlNpeMgrUtilsStats.contextRegWrites = 0;
ixNpeDlNpeMgrUtilsStats.nextPcWrites = 0;
ixNpeDlNpeMgrUtilsStats.dbgInstructionExecs = 0;
}