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/*******************************************************************************
Copyright (C) Marvell International Ltd. and its affiliates
This software file (the "File") is owned and distributed by Marvell
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********************************************************************************
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* Redistributions of source code must retain the above copyright notice,
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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
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SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*******************************************************************************/
#include "ctrlEnv/mvCtrlEnvLib.h"
#include "ctrlEnv/mvCtrlEnvSpec.h"
#include "boardEnv/mvBoardEnvLib.h"
#include "ctrlEnv/sys/mvCpuIf.h"
#include "cpu/mvCpu.h"
#include "cntmr/mvCntmr.h"
#include "gpp/mvGpp.h"
#include "twsi/mvTwsi.h"
#include "pex/mvPex.h"
#include "device/mvDevice.h"
#include "gpp/mvGppRegs.h"
#include "ctrlEnv/mvCtrlEthCompLib.h"
#if defined(CONFIG_MV_ETH_LEGACY)
#include "eth/gbe/mvEthGbe.h"
#else
#include "neta/gbe/mvNeta.h"
#endif /* CONFIG_MV_ETH_LEGACY or CONFIG_MV_ETH_NETA */
/* defines */
/* #define MV_DEBUG */
#ifdef MV_DEBUG
#define DB(x) x
#else
#define DB(x)
#endif
extern MV_CPU_ARM_CLK _cpuARMDDRCLK[];
extern MV_BOARD_INFO *boardInfoTbl[];
#define BOARD_INFO(boardId) boardInfoTbl[boardId - BOARD_ID_BASE]
/* Locals */
static MV_DEV_CS_INFO *boardGetDevEntry(MV_32 devNum, MV_BOARD_DEV_CLASS devClass);
MV_U32 tClkRate = -1;
#define MV_BRD_MODULE_CFG_BUILD(ethCfg, tdmCfg) ((tdmCfg << 24) | ethCfg)
#define MV_BRD_MODULE_CFG_ETH_GET(config) (config & 0xFFFFFF)
#define MV_BRD_MODULE_CFG_TDM_GET(config) (MV_8)(config >> 24)
static MV_BOOL mvBoardStaticModuleConfig = MV_FALSE;
static MV_U32 mvBoardModuleConfig = 0;
/*******************************************************************************
* mvBoardEnvInit - Init board
*
* DESCRIPTION:
* In this function the board environment take care of device bank
* initialization.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_VOID mvBoardEnvInit(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
MV_U32 nandDev;
MV_32 width;
MV_BOARD_INFO *pBoardInfo;
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardEnvInit:Board unknown.\n");
return;
}
pBoardInfo = mvBoardInfoGet();
if (pBoardInfo->pBoardEnvInit)
pBoardInfo->pBoardEnvInit(pBoardInfo);
nandDev = boardGetDevCSNum(0, BOARD_DEV_NAND_FLASH);
if (nandDev != 0xFFFFFFFF) {
/* Set NAND interface access parameters */
nandDev = BOOT_CS;
if (BOARD_INFO(boardId)->nandFlashParamsValid == MV_TRUE) {
MV_REG_WRITE(DEV_BANK_PARAM_REG(nandDev), BOARD_INFO(boardId)->nandFlashReadParams);
MV_REG_WRITE(DEV_BANK_PARAM_REG_WR(nandDev), BOARD_INFO(boardId)->nandFlashWriteParams);
MV_REG_WRITE(DEV_NAND_CTRL_REG, BOARD_INFO(boardId)->nandFlashControl);
}
}
width = mvBoardGetDeviceWidth(0, BOARD_DEV_NOR_FLASH);
if (width != 0xFFFFFFFF)
mvDevWidthSet(BOOT_CS, width);
/* Set GPP Out value */
MV_REG_WRITE(GPP_DATA_OUT_REG(0), BOARD_INFO(boardId)->gppOutValLow);
MV_REG_WRITE(GPP_DATA_OUT_REG(1), BOARD_INFO(boardId)->gppOutValMid);
if ((boardId != DB_88F6601_BP_ID) && (boardId != RD_88F6601_MC_ID)
&& (boardId != GFLT400_ID) && (boardId != GFLT300_ID)
&& (boardId != GFLT200_ID) && (boardId != GFLT110_ID))
MV_REG_WRITE(GPP_DATA_OUT_REG(2), BOARD_INFO(boardId)->gppOutValHigh);
/* set GPP polarity */
mvGppPolaritySet(0, 0xFFFFFFFF, BOARD_INFO(boardId)->gppPolarityValLow);
mvGppPolaritySet(1, 0xFFFFFFFF, BOARD_INFO(boardId)->gppPolarityValMid);
if ((boardId != DB_88F6601_BP_ID) && (boardId != RD_88F6601_MC_ID)
&& (boardId != GFLT400_ID) && (boardId != GFLT300_ID)
&& (boardId != GFLT200_ID) && (boardId != GFLT110_ID))
mvGppPolaritySet(2, 0xFFFFFFFF, BOARD_INFO(boardId)->gppPolarityValHigh);
/* Set GPP Out Enable */
mvGppTypeSet(0, 0xFFFFFFFF, BOARD_INFO(boardId)->gppOutEnValLow);
mvGppTypeSet(1, 0xFFFFFFFF, BOARD_INFO(boardId)->gppOutEnValMid);
if ((boardId != DB_88F6601_BP_ID) && (boardId != RD_88F6601_MC_ID)
&& (boardId != GFLT400_ID) && (boardId != GFLT300_ID)
&& (boardId != GFLT200_ID) && (boardId != GFLT110_ID))
mvGppTypeSet(2, 0xFFFFFFFF, BOARD_INFO(boardId)->gppOutEnValHigh);
/* Nand CE */
#if 0
if (nandDev != 0xFFFFFFFF)
mvDevNandDevCsSet(nandDev, MV_TRUE);
#endif
}
/*******************************************************************************
* mvBoardModelGet - Get Board model
*
* DESCRIPTION:
* This function returns 16bit describing board model.
* Board model is constructed of one byte major and minor numbers in the
* following manner:
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* String describing board model.
*
*******************************************************************************/
MV_U16 mvBoardModelGet(MV_VOID)
{
return (mvBoardIdGet() >> 16);
}
/*******************************************************************************
* mbBoardRevlGet - Get Board revision
*
* DESCRIPTION:
* This function returns a 32bit describing the board revision.
* Board revision is constructed of 4bytes. 2bytes describes major number
* and the other 2bytes describes minor munber.
* For example for board revision 3.4 the function will return
* 0x00030004.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* String describing board model.
*
*******************************************************************************/
MV_U16 mvBoardRevGet(MV_VOID)
{
return (mvBoardIdGet() & 0xFFFF);
}
/*******************************************************************************
* mvBoardNameGet - Get Board name
*
* DESCRIPTION:
* This function returns a string describing the board model and revision.
* String is extracted from board I2C EEPROM.
*
* INPUT:
* None.
*
* OUTPUT:
* pNameBuff - Buffer to contain board name string. Minimum size 32 chars.
*
* RETURN:
*
* MV_ERROR if informantion can not be read.
*******************************************************************************/
MV_STATUS mvBoardNameGet(char *pNameBuff)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsSPrintf(pNameBuff, "Board unknown.\n");
return MV_ERROR;
}
mvOsSPrintf(pNameBuff, "%s", BOARD_INFO(boardId)->boardName);
return MV_OK;
}
/*******************************************************************************
* mvBoardSpecInitGet -
*
* DESCRIPTION:
* This routine returns the board specific initializtion information.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* A pointer to the array holding the board specific initializations.
*
*******************************************************************************/
MV_BOARD_SPEC_INIT *mvBoardSpecInitGet(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSpecInitGet: Board unknown.\n");
return NULL;
}
return BOARD_INFO(boardId)->pBoardSpecInit;
}
/*******************************************************************************
* mvBoardPwrUpDelayGet -
*
* DESCRIPTION:
* This routine returns the power up delay in clock cycles.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* The power up delay or 0 in case of failure.
*
*******************************************************************************/
MV_U32 mvBoardPwrUpDelayGet(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardPwrUpDelayGet: Board unknown.\n");
return 0;
}
return BOARD_INFO(boardId)->deepIdlePwrUpDelay;
}
/*******************************************************************************
* mvBoardIsPortInSgmii -
*
* DESCRIPTION:
* This routine returns MV_TRUE for port number works in SGMII or MV_FALSE
* For all other options.
*
* INPUT:
* ethPortNum - Ethernet port number.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_TRUE - port in SGMII.
* MV_FALSE - other.
*
*******************************************************************************/
MV_BOOL mvBoardIsPortInSgmii(MV_U32 ethPortNum)
{
MV_U32 ethCompOpt;
if (ethPortNum >= BOARD_ETH_PORT_NUM) {
mvOsPrintf("Invalid portNo=%d\n", ethPortNum);
return MV_FALSE;
}
ethCompOpt = mvBoardEthComplexConfigGet();
if (DB_88F6601_BP_ID == mvBoardIdGet()) {
if (ethPortNum == 0) {
if (ethCompOpt & ESC_OPT_GEPHY_MAC0)
return MV_FALSE;
return MV_TRUE;
}
if (ethCompOpt & ESC_OPT_GEPHY_MAC0)
return MV_TRUE;
return MV_FALSE;
}
if ((RD_88F6601_MC_ID == mvBoardIdGet()) ||
(GFLT400_ID == mvBoardIdGet()) || (GFLT300_ID == mvBoardIdGet()) ||
(GFLT200_ID == mvBoardIdGet()) || (GFLT110_ID == mvBoardIdGet()))
return MV_FALSE;
if ((ethPortNum > 0) || (ethCompOpt & ESC_OPT_SGMII_2_SW_P1))
return MV_FALSE;
return ((ethCompOpt & (ESC_OPT_SGMII | ESC_OPT_SGMII_2_5)) ? MV_TRUE : MV_FALSE);
}
/*******************************************************************************
* mvBoardIsPortInRgmii -
*
* DESCRIPTION:
* This routine returns MV_TRUE for port number works in RGMII or MV_FALSE
* for all other options.
*
* INPUT:
* ethPortNum - Ethernet port number.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_TRUE - port in RGMII.
* MV_FALSE - other.
*
*******************************************************************************/
MV_BOOL mvBoardIsPortInRgmii(MV_U32 ethPortNum)
{
MV_U32 ethCompOpt;
if (ethPortNum >= BOARD_ETH_PORT_NUM) {
mvOsPrintf("Invalid portNo=%d\n", ethPortNum);
return MV_FALSE;
}
ethCompOpt = mvBoardEthComplexConfigGet();
if (ethPortNum == 0)
return (ethCompOpt & (ESC_OPT_RGMIIA_MAC0 | ESC_OPT_RGMIIB_MAC0)) ? MV_TRUE : MV_FALSE;
else if (ethPortNum == 1)
return (ethCompOpt & ESC_OPT_RGMIIA_MAC1) ? MV_TRUE : MV_FALSE;
else
return MV_FALSE;
}
/*******************************************************************************
* mvBoardEthPortsModeGet -
*
* DESCRIPTION:
* This routine returns a bitmask of the ethernet ports MAC mode (RGMII /
* MII ...).
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* Bitmask of ethernet ports mode.
*
*******************************************************************************/
MV_U32 mvBoardEthPortsModeGet(void)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardPhyAddrGet: Board unknown.\n");
return MV_ERROR;
}
return BOARD_INFO(boardId)->pBoardMppTypeValue->ethPortsMode;
}
#if 0
/*******************************************************************************
* mvBoardIsPortInGmii -
*
* DESCRIPTION:
* This routine returns MV_TRUE for port number works in GMII or MV_FALSE
* For all other options.
*
* INPUT:
*
* OUTPUT:
* None.
*
* RETURN:
* MV_TRUE - port in GMII.
* MV_FALSE - other.
*
*******************************************************************************/
MV_BOOL mvBoardIsPortInGmii(MV_VOID)
{
MV_U32 devClassId, devClass = 0;
if (mvBoardMppGroupTypeGet(devClass) == MV_BOARD_AUTO) {
/* Get MPP module ID */
devClassId = mvBoarModuleTypeGet(devClass);
if (MV_BOARD_MODULE_GMII_ID == devClassId)
return MV_TRUE;
} else if (mvBoardMppGroupTypeGet(devClass) == MV_BOARD_GMII)
return MV_TRUE;
return MV_FALSE;
}
#endif /* 0 */
/*******************************************************************************
* mvBoardPhyAddrGet - Get the phy address
*
* DESCRIPTION:
* This routine returns the Phy address of a given ethernet port.
*
* INPUT:
* ethPortNum - Ethernet port number.
*
* OUTPUT:
* None.
*
* RETURN:
* 32bit describing Phy address, -1 if the port number is wrong.
*
*******************************************************************************/
MV_32 mvBoardPhyAddrGet(MV_U32 ethPortNum)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardPhyAddrGet: Board unknown.\n");
return MV_ERROR;
}
return BOARD_INFO(boardId)->pBoardMacInfo[ethPortNum].boardEthSmiAddr;
}
/*******************************************************************************
* mvBoardPhyAddrSet
*
* DESCRIPTION:
* Set the PHY address for a given ethernet port in the board
* specification structure.
*
* INPUT:
* ethPortNum - Ethernet port number.
* phyAddr - The PHY address to set.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_OK on success.
*
*******************************************************************************/
MV_STATUS mvBoardPhyAddrSet(MV_U32 ethPortNum, MV_32 phyAddr)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardPhyAddrGet: Board unknown.\n");
return MV_ERROR;
}
BOARD_INFO(boardId)->pBoardMacInfo[ethPortNum].boardEthSmiAddr = phyAddr;
return MV_OK;
}
/*******************************************************************************
* mvBoardMacSpeedGet - Get the Mac speed
*
* DESCRIPTION:
* This routine returns the Mac speed if pre define of a given ethernet port.
*
* INPUT:
* ethPortNum - Ethernet port number.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_BOARD_MAC_SPEED, -1 if the port number is wrong.
*
*******************************************************************************/
MV_BOARD_MAC_SPEED mvBoardMacSpeedGet(MV_U32 ethPortNum)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardMacSpeedGet: Board unknown.\n");
return MV_ERROR;
}
if (ethPortNum >= BOARD_INFO(boardId)->numBoardMacInfo) {
mvOsPrintf("mvBoardMacSpeedGet: illegal port number\n");
return MV_ERROR;
}
return BOARD_INFO(boardId)->pBoardMacInfo[ethPortNum].boardMacSpeed;
}
/*******************************************************************************
* mvBoardMacSpeedSet
*
* DESCRIPTION:
* This routine sets the Mac speed of a given ethernet port.
*
* INPUT:
* ethPortNum - Ethernet port number.
* speed - Port speed to be set.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_OK on success.
*
*******************************************************************************/
MV_STATUS mvBoardMacSpeedSet(MV_U32 ethPortNum, MV_BOARD_MAC_SPEED speed)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardMacSpeedGet: Board unknown.\n");
return MV_ERROR;
}
BOARD_INFO(boardId)->pBoardMacInfo[ethPortNum].boardMacSpeed = speed;
return MV_OK;
}
/*******************************************************************************
* mvBoardIsInternalSwitchConnected
*
* DESCRIPTION:
* This routine returns port's connection status
*
* INPUT:
* ethPortNum - Ethernet port number.
*
* OUTPUT:
* None.
*
* RETURN:
* 1 - if ethPortNum is connected to switch, 0 otherwise
*
*******************************************************************************/
MV_STATUS mvBoardIsInternalSwitchConnected(MV_U32 ethPortNum)
{
MV_U32 boardId = mvBoardIdGet();
MV_U32 ethCompOpt;
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardIsInternalSwitchConnected: Board unknown.\n");
return MV_FALSE;
}
if (ethPortNum >= BOARD_INFO(boardId)->numBoardMacInfo) {
mvOsPrintf("mvBoardIsSwitchConnected: Illegal port number(%u)\n", ethPortNum);
return MV_FALSE;
}
/* Check if internal switch is connected */
ethCompOpt = mvBoardEthComplexConfigGet();
if ((ethPortNum == 0) && (ethCompOpt & ESC_OPT_MAC0_2_SW_P4))
return MV_TRUE;
else if ((ethPortNum == 1) && (ethCompOpt & ESC_OPT_MAC1_2_SW_P5))
return MV_TRUE;
else
return MV_FALSE;
}
/*******************************************************************************
* mvBoardSwitchNumPortsGet
*
* DESCRIPTION:
* This routine returns the number of switch ports.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* Number of switch ports, 0 - if no switch is connected.
*
*******************************************************************************/
MV_32 mvBoardSwitchNumPortsGet(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
MV_U32 ethCompOpt;
MV_U32 numPorts = 0;
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSwitchNumPortsGet: Board unknown.\n");
return MV_ERROR;
}
if ((RD_88F6601_MC_ID == boardId) || (DB_88F6601_BP_ID == boardId)
|| (GFLT400_ID == boardId) || (GFLT300_ID == boardId)
|| (GFLT200_ID == boardId) || (GFLT110_ID == boardId))
{
return 0;
}
/* Check if internal switch is connected */
ethCompOpt = mvBoardEthComplexConfigGet();
if (ethCompOpt & (ESC_OPT_MAC0_2_SW_P4 | ESC_OPT_MAC1_2_SW_P5)) {
if (ethCompOpt & ESC_OPT_FE3PHY)
numPorts += 3;
if (ethCompOpt & ESC_OPT_QSGMII)
numPorts += 4;
if (ethCompOpt & (ESC_OPT_GEPHY_SW_P0 | ESC_OPT_GEPHY_SW_P5))
numPorts += 1;
if (ethCompOpt & (ESC_OPT_RGMIIA_SW_P5 | ESC_OPT_RGMIIA_SW_P6))
numPorts += 1;
if (ethCompOpt & ESC_OPT_SGMII)
numPorts += 1;
}
return numPorts;
}
/*******************************************************************************
* mvBoardIsQsgmiiModuleConnected
*
* DESCRIPTION:
* This routine returns whether the QSGMII module is connected or not.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_TRUE if QSGMII module is connected, MV_FALSE otherwise.
*
*******************************************************************************/
MV_BOOL mvBoardIsQsgmiiModuleConnected(MV_VOID)
{
MV_U32 ethCompOpt;
/* Check if internal switch is connected */
ethCompOpt = mvBoardEthComplexConfigGet();
if (ethCompOpt & (ESC_OPT_MAC0_2_SW_P4 | ESC_OPT_MAC1_2_SW_P5)) {
if (ethCompOpt & ESC_OPT_QSGMII)
return MV_TRUE;
}
return MV_FALSE;
}
/*******************************************************************************
* mvBoardGePhySwitchPortGet
*
* DESCRIPTION:
* This routine returns whether the internal GE PHY is connected to
* Switch Port 0, Switch port 5 or not connected to any Switch port.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* 0 if the internal GE PHY is connected to Switch Port 0,
* 5 if the internal GE PHY is connected to Switch Port 5,
* -1 otherwise.
*
*******************************************************************************/
MV_32 mvBoardGePhySwitchPortGet(MV_VOID)
{
MV_U32 ethCompOpt;
/* Check if internal switch is connected */
ethCompOpt = mvBoardEthComplexConfigGet();
if (ethCompOpt & (ESC_OPT_MAC0_2_SW_P4 | ESC_OPT_MAC1_2_SW_P5)) {
if (ethCompOpt & ESC_OPT_GEPHY_SW_P0)
return 0;
if (ethCompOpt & ESC_OPT_GEPHY_SW_P5)
return 5;
}
return -1;
}
/*******************************************************************************
* mvBoardRgmiiASwitchPortGet
*
* DESCRIPTION:
* This routine returns whether RGMII-A is connected to
* Switch Port 5, Switch port 6 or not connected to any Switch port.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* 5 if the internal GE PHY is connected to Switch Port 5,
* 6 if the internal GE PHY is connected to Switch Port 6,
* -1 otherwise.
*
*******************************************************************************/
MV_32 mvBoardRgmiiASwitchPortGet(MV_VOID)
{
MV_U32 ethCompOpt;
/* Check if internal switch is connected */
ethCompOpt = mvBoardEthComplexConfigGet();
if (ethCompOpt & (ESC_OPT_MAC0_2_SW_P4 | ESC_OPT_MAC1_2_SW_P5)) {
if (ethCompOpt & ESC_OPT_RGMIIA_SW_P5)
return 5;
if (ethCompOpt & ESC_OPT_RGMIIA_SW_P6)
return 6;
}
return -1;
}
/*******************************************************************************
* mvBoardSwitchInfoUpdate
*
* DESCRIPTION:
* Update switch information structure according to modules detection
* result.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_OK - on success,
* MV_ERROR - On failure.
*
*******************************************************************************/
MV_STATUS mvBoardSwitchInfoUpdate(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
MV_U32 ethCompOpt;
MV_U32 i;
MV_U32 swIdx = 0;
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSwitchInfoUpdate: Board unknown.\n");
return MV_ERROR;
}
if (MV_6601_DEV_ID == mvCtrlModelGet()){ /* no switch on A-MC */
BOARD_INFO(boardId)->switchInfoNum = 0;
return MV_OK;
}
if (!mvBoardModuleAutoDetectEnabled())
return MV_OK;
if ((!mvBoardIsInternalSwitchConnected(0)) && (!mvBoardIsInternalSwitchConnected(1))) {
BOARD_INFO(boardId)->switchInfoNum = 0;
return MV_OK;
}
ethCompOpt = mvBoardEthComplexConfigGet();
/* Update the cpuPort & connectedPort fields */
BOARD_INFO(boardId)->pSwitchInfo[swIdx].cpuPort = -1;
for (i = 0; i < MV_ETH_MAX_PORTS; i++)
BOARD_INFO(boardId)->pSwitchInfo[swIdx].connectedPort[i] = -1;
/* Check if port 4 connected to MAC0 */
if (ethCompOpt & ESC_OPT_MAC0_2_SW_P4) {
BOARD_INFO(boardId)->pSwitchInfo[swIdx].cpuPort = 4;
BOARD_INFO(boardId)->pSwitchInfo[swIdx].connectedPort[0] = 4;
}
/* Check if port 5 connected to MAC1 */
if (ethCompOpt & ESC_OPT_MAC1_2_SW_P5) {
BOARD_INFO(boardId)->pSwitchInfo[swIdx].cpuPort = 5;
BOARD_INFO(boardId)->pSwitchInfo[swIdx].connectedPort[1] = 5;
}
i = 0;
if (ethCompOpt & (ESC_OPT_MAC0_2_SW_P4 | ESC_OPT_MAC1_2_SW_P5)) {
if (ethCompOpt & ESC_OPT_QSGMII) {
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[0] = 0;
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[1] = 1;
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[2] = 2;
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[3] = 3;
i = 4;
} else if (ethCompOpt & ESC_OPT_FE3PHY) {
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[0] = 1;
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[1] = 2;
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[2] = 3;
i = 3;
}
else if (ethCompOpt & ESC_OPT_SGMII_2_SW_P1) {
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[0] = -1;
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[1] = 0;
i = 2;
}
if (ethCompOpt & ESC_OPT_GEPHY_SW_P0)
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[i++] = 0;
else if (ethCompOpt & ESC_OPT_GEPHY_SW_P5)
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[i++] = 5;
if (ethCompOpt & ESC_OPT_RGMIIA_SW_P6)
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[i++] = 6;
}
/* Set all unused switch ports to -1 */
for (; i < BOARD_ETH_SWITCH_PORT_NUM; i++)
BOARD_INFO(boardId)->pSwitchInfo[swIdx].switchPort[i] = -1;
/* Set number of switch entries */
BOARD_INFO(boardId)->switchInfoNum = 1;
if (mvBoardSwitchSnglChipAddModeGet() == MV_TRUE) {
/* Set switch access mode according to number of SMI clients. */
if (!(ethCompOpt & (ESC_OPT_RGMIIA_MAC0 | ESC_OPT_RGMIIA_MAC1 |
ESC_OPT_RGMIIB_MAC0 | ESC_OPT_GEPHY_MAC1 | ESC_OPT_SGMII | ESC_OPT_SGMII_2_5))) {
BOARD_INFO(boardId)->pSwitchInfo[swIdx].smiScanMode = 1;
/* Set switch PHY address to 0x0 to indicate single-address
** mode.
*/
if (ethCompOpt & ESC_OPT_MAC0_2_SW_P4)
mvBoardPhyAddrSet(0, 0x0);
else if (ethCompOpt & ESC_OPT_MAC1_2_SW_P5)
mvBoardPhyAddrSet(1, 0x0);
}
}
return MV_OK;
}
/*******************************************************************************
* mvBoardSwitchSnlgChipAddModeGet
*
* DESCRIPTION:
* Check if this board enables single-chip address mode for switch registers
* access.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_TRUE - If single-chip address mode is enabled.
* MV_FALSE - If disabled.
*
*******************************************************************************/
MV_BOOL mvBoardSwitchSnglChipAddModeGet(MV_VOID)
{
MV_U8 temp;
temp = mvBoardTwsiSatRGet(MV_BOARD_SWITCH_SCAN_MODE_SATR_IDX, 1);
if (MV_BOARD_SWITCH_SCAN_MODE(temp))
return MV_TRUE;
else
return MV_FALSE;
}
/*******************************************************************************
* mvBoardSwitchSnglChipAddModeSet
*
* DESCRIPTION:
* Enabled / Disable single-chip address mode for switch registers access.
*
* INPUT:
* enable - MV_TRUE to enable, MV_FALSE to disable.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_OK on success,
* MV_ERROR otherwise.
*
*******************************************************************************/
MV_STATUS mvBoardSwitchSnglChipAddModeSet(MV_BOOL enable)
{
MV_U8 temp;
temp = mvBoardTwsiSatRGet(MV_BOARD_SWITCH_SCAN_MODE_SATR_IDX, 1);
temp &= ~MV_BOARD_SWITCH_SCAN_MODE_MASK;
if (enable == MV_TRUE)
temp |= 1;
return mvBoardTwsiSatRSet(MV_BOARD_SWITCH_SCAN_MODE_SATR_IDX, 1, temp);
}
/*******************************************************************************
* mvBoardSwitchIrqGet - Get the IRQ number for the link status indication
*
* DESCRIPTION:
* This routine returns the IRQ number for the link status indication.
*
* INPUT:
* ethPortNum - Ethernet port number.
*
* OUTPUT:
* None.
*
* RETURN:
* the number of the IRQ for the link status indication, -1 if the port
* number is wrong or if not relevant.
*
*******************************************************************************/
MV_32 mvBoardSwitchIrqGet(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardLinkStatusIrqGet: Board unknown.\n");
return -1;
}
if (BOARD_INFO(boardId)->switchInfoNum == 0)
return -1;
return BOARD_INFO(boardId)->pSwitchInfo[0].switchIrq;
}
/*******************************************************************************
* mvBoardSwitchConnectedPortGet -
*
* DESCRIPTION:
* This routine returns the switch port connected to the ethPort
*
* INPUT:
* ethPortNum - Ethernet port number.
*
* OUTPUT:
* None.
*
* RETURN:
*
*******************************************************************************/
MV_32 mvBoardSwitchConnectedPortGet(MV_U32 ethPort)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSwitchConnectedPortGet: Board unknown.\n");
return -1;
}
if (BOARD_INFO(boardId)->switchInfoNum == 0)
return -1;
return BOARD_INFO(boardId)->pSwitchInfo[0].connectedPort[ethPort];
}
/*******************************************************************************
* mvBoardSwitchPortGet - Get the mapping between the board connector and the
* Ethernet Switch port
*
* DESCRIPTION:
* This routine returns the matching Switch port.
*
* INPUT:
* boardPortNum - logical number of the connector on the board
*
* OUTPUT:
* None.
*
* RETURN:
* the matching Switch port, -1 if the port number is wrong or if not relevant.
*
*******************************************************************************/
MV_32 mvBoardSwitchPortGet(MV_U32 switchIdx, MV_U32 boardPortNum)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSwitchPortGet: Board unknown.\n");
return -1;
}
if (boardPortNum >= BOARD_ETH_SWITCH_PORT_NUM) {
mvOsPrintf("mvBoardSwitchPortGet: Illegal board port number.\n");
return -1;
}
if ((BOARD_INFO(boardId)->switchInfoNum == 0) || (switchIdx >= BOARD_INFO(boardId)->switchInfoNum))
return -1;
return BOARD_INFO(boardId)->pSwitchInfo[switchIdx].switchPort[boardPortNum];
}
/*******************************************************************************
* mvBoardSwitchPortMap
*
* DESCRIPTION:
* Map front panel connector number to switch port number.
*
* INPUT:
* switchIdx - The switch index.
* switchPortNum - The switch port number to get the mapping for.
*
* OUTPUT:
* None.
*
* RETURN:
* The switch port mapping.
* OR -1 if the port number is wrong or if not relevant.
*
*******************************************************************************/
MV_32 mvBoardSwitchPortMap(MV_U32 switchIdx, MV_U32 switchPortNum)
{
int i;
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSwitchPortMap: Board unknown.\n");
return -1;
}
if ((BOARD_INFO(boardId)->switchInfoNum == 0) || (switchIdx >= BOARD_INFO(boardId)->switchInfoNum))
return -1;
for (i = 0; i < BOARD_ETH_SWITCH_PORT_NUM; i++) {
if (BOARD_INFO(boardId)->pSwitchInfo[switchIdx].switchPort[i] == switchPortNum)
return i;
}
return -1;
}
/*******************************************************************************
* mvBoardSwitchCpuPortGet - Get the the Ethernet Switch CPU port
*
* DESCRIPTION:
* This routine returns the Switch CPU port.
*
* INPUT:
* switchIdx - index of the switch. Only 0 is supported.
*
* OUTPUT:
* None.
*
* RETURN:
* the Switch CPU port, -1 if the switch is not connected.
*
*******************************************************************************/
MV_32 mvBoardSwitchCpuPortGet(MV_U32 switchIdx)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSwitchCpuPortGet: Board unknown.\n");
return -1;
}
if ((BOARD_INFO(boardId)->switchInfoNum == 0) || (switchIdx >= BOARD_INFO(boardId)->switchInfoNum))
return -1;
return BOARD_INFO(boardId)->pSwitchInfo[switchIdx].cpuPort;
}
/*******************************************************************************
* mvBoardSwitchPortForceLinkGet
*
* DESCRIPTION:
* Return the switch ports force link bitmask.
*
* INPUT:
* switchIdx - index of the switch. Only 0 is supported.
*
* OUTPUT:
* None.
*
* RETURN:
* the ports bitmask, -1 if the switch is not connected.
*
*******************************************************************************/
MV_U32 mvBoardSwitchPortForceLinkGet(MV_U32 switchIdx)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSwitchCpuPortGet: Board unknown.\n");
return -1;
}
if ((BOARD_INFO(boardId)->switchInfoNum == 0) || (switchIdx >= BOARD_INFO(boardId)->switchInfoNum))
return -1;
return BOARD_INFO(boardId)->pSwitchInfo[switchIdx].forceLinkMask;
}
/*******************************************************************************
* mvBoardSmiScanModeGet - Get Switch SMI scan mode
*
* DESCRIPTION:
* This routine returns Switch SMI scan mode.
*
* INPUT:
* switchIdx - index of the switch. Only 0 is supported.
*
* OUTPUT:
* None.
*
* RETURN:
* 1 for SMI_MANUAL_MODE, -1 if the port number is wrong or if not relevant.
*
*******************************************************************************/
MV_32 mvBoardSmiScanModeGet(MV_U32 switchIdx)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardSmiScanModeGet: Board unknown.\n");
return -1;
}
if ((BOARD_INFO(boardId)->switchInfoNum == 0) || (switchIdx >= BOARD_INFO(boardId)->switchInfoNum))
return -1;
return BOARD_INFO(boardId)->pSwitchInfo[switchIdx].smiScanMode;
}
/*******************************************************************************
* mvBoardQuadPhyAddrGet - Get QUAD phy SMI address.
*
* DESCRIPTION:
* This routine returns the external QUAD phy address.
*
* INPUT:
* switchIdx - index of the switch. Only 0 is supported.
*
* OUTPUT:
* None.
*
* RETURN:
* The QUAD phy start address or -1 if error.
*
*******************************************************************************/
MV_32 mvBoardQuadPhyAddrGet(MV_U32 switchIdx)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardQuadPhyAddrGet: Board unknown.\n");
return -1;
}
if ((BOARD_INFO(boardId)->switchInfoNum == 0) || (switchIdx >= BOARD_INFO(boardId)->switchInfoNum))
return -1;
return BOARD_INFO(boardId)->pSwitchInfo[switchIdx].quadPhyAddr;
}
/*******************************************************************************
* mvBoardPhySpecInitGet -
*
* DESCRIPTION:
*
* INPUT:
*
* OUTPUT:
* None.
*
* RETURN: Return MV_TRUE and parameters in case board need spesific phy init,
* otherwise return MV_FALSE.
*
*
*******************************************************************************/
MV_BOOL mvBoardPhySpecInitGet(MV_U32 *regOff, MV_U32 *data)
{
return MV_FALSE;
}
/*******************************************************************************
* mvBoardTclkGet - Get the board Tclk (Controller clock)
*
* DESCRIPTION:
* This routine extract the controller core clock.
* This function uses the controller counters to make identification.
* Note: In order to avoid interference, make sure task context switch
* and interrupts will not occure during this function operation
*
* INPUT:
* countNum - Counter number.
*
* OUTPUT:
* None.
*
* RETURN:
* 32bit clock cycles in Hertz.
*
*******************************************************************************/
MV_U32 mvBoardTclkGet(MV_VOID)
{
#if defined(TCLK_AUTO_DETECT)
MV_U32 tmpTClkRate = MV_BOARD_TCLK_166MHZ;
MV_U32 boardId = mvBoardIdGet();
tmpTClkRate = MV_REG_READ(MPP_SAMPLE_AT_RESET(0));
if ((RD_88F6601_MC_ID == boardId) || (DB_88F6601_BP_ID == boardId)
|| (GFLT400_ID == boardId) || (GFLT300_ID == boardId)
|| (GFLT200_ID == boardId) || (GFLT110_ID == boardId)) {
tmpTClkRate &= MSAR_TCLCK_6601_MASK;
if (tmpTClkRate )
return MV_BOARD_TCLK_200MHZ;
else
return MV_BOARD_TCLK_166MHZ;
} else {
tmpTClkRate &= MSAR_TCLCK_MASK;
switch (tmpTClkRate) {
case MSAR_TCLCK_166:
return MV_BOARD_TCLK_166MHZ;
break;
case MSAR_TCLCK_200:
return MV_BOARD_TCLK_200MHZ;
break;
default:
return -1;
}
}
#else
return MV_BOARD_TCLK_200MHZ;
#endif
}
/*******************************************************************************
* mvBoardSysClkGet - Get the board SysClk (CPU bus clock)
*
* DESCRIPTION:
* This routine extract the CPU bus clock.
*
* INPUT:
* countNum - Counter number.
*
* OUTPUT:
* None.
*
* RETURN:
* 32bit clock cycles in Hertz.
*
*******************************************************************************/
MV_U32 mvBoardSysClkGet(MV_VOID)
{
#ifdef SYSCLK_AUTO_DETECT
MV_U32 i, res = -1;
MV_U32 sar0;
MV_U32 clockSatr;
MV_CPU_ARM_CLK cpuDdrL2Tbl[] = MV_CPU_DDR_L2_CLCK_TBL;
MV_CPU_ARM_CLK cpuDdrTbl6601[] = MV6601_CPU_DDR_CLCK_TBL;
MV_U32 boardId = mvBoardIdGet();
/* Read S@R registers value */
sar0 = MV_REG_READ(MPP_SAMPLE_AT_RESET(0));
clockSatr = MSAR_CPU_DDR_L2_CLCK_EXTRACT(sar0);
i = 0;
if ((RD_88F6601_MC_ID == boardId) || (DB_88F6601_BP_ID == boardId)
|| (GFLT400_ID == boardId) || (GFLT300_ID == boardId)
|| (GFLT200_ID == boardId) || (GFLT110_ID == boardId)) {
while (cpuDdrTbl6601[i].satrValue != -1) {
if (cpuDdrTbl6601[i].satrValue == clockSatr) {
res = i;
break;
}
i++;
}
if (res == 0xFFFFFFFF)
return 0;
else
return cpuDdrTbl6601[i].ddrClk;
} else {
/* Search for a matching entry */
while (cpuDdrL2Tbl[i].satrValue != -1) {
if (cpuDdrL2Tbl[i].satrValue == clockSatr) {
res = i;
break;
}
i++;
}
if (res == 0xFFFFFFFF)
return 0;
else
return cpuDdrL2Tbl[i].ddrClk;
}
#else
return MV_BOARD_DEFAULT_SYSCLK;
#endif
}
/*******************************************************************************
* mvBoardDebugLedNumGet - Get number of debug Leds
*
* DESCRIPTION:
* INPUT:
* boardId
*
* OUTPUT:
* None.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_U32 mvBoardDebugLedNumGet(MV_U32 boardId)
{
return BOARD_INFO(boardId)->activeLedsNumber;
}
/*******************************************************************************
* mvBoardDebugLeg - Set the board debug Leds
*
* DESCRIPTION: turn on/off status leds.
*
*
* INPUT:
* hexNum - Number to be displied in hex by Leds.
* Note: assuming all debug leds reside within same group.
*
* OUTPUT:
* None.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_VOID mvBoardDebugLed(MV_U32 hexNum)
{
MV_U32 val = 0, totalMask, currentBitMask = 1, i;
MV_U8 group = 0;
MV_U32 boardId = mvBoardIdGet();
if (BOARD_INFO(boardId)->pLedGppPin == NULL)
return;
totalMask = (1 << BOARD_INFO(boardId)->activeLedsNumber) - 1;
hexNum &= totalMask;
totalMask = 0;
group = (BOARD_INFO(boardId)->pLedGppPin[0] / 32);
for (i = 0; i < BOARD_INFO(boardId)->activeLedsNumber; i++) {
if (hexNum & currentBitMask)
val |= (1 << (BOARD_INFO(boardId)->pLedGppPin[i] % 32));
totalMask |= (1 << (BOARD_INFO(boardId)->pLedGppPin[i] % 32));
currentBitMask = (currentBitMask << 1);
}
if (BOARD_INFO(boardId)->ledsPolarity)
mvGppValueSet(group, totalMask, val);
else
mvGppValueSet(group, totalMask, ~val);
}
/*******************************************************************************
* mvBoarGpioPinGet - mvBoarGpioPinGet
*
* DESCRIPTION:
*
* INPUT:
* gppClass - MV_BOARD_GPP_CLASS enum.
*
* OUTPUT:
* None.
*
* RETURN:
* GPIO pin number. The function return -1 for bad parameters.
*
*******************************************************************************/
MV_32 mvBoarGpioPinNumGet(MV_BOARD_GPP_CLASS gppClass, MV_U32 index)
{
MV_U32 boardId, i;
MV_U32 indexFound = 0;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardRTCGpioPinGet:Board unknown.\n");
return MV_ERROR;
}
for (i = 0; i < BOARD_INFO(boardId)->numBoardGppInfo; i++) {
if (BOARD_INFO(boardId)->pBoardGppInfo[i].devClass == gppClass) {
if (indexFound == index)
return (MV_U32) BOARD_INFO(boardId)->pBoardGppInfo[i].gppPinNum;
indexFound++;
}
}
return MV_ERROR;
}
MV_STATUS mvBoardGppInfoGet(MV_BOARD_GPP_CLASS gppClass, MV_U32 index, MV_U8 *pinNum, MV_U8 *polarity)
{
MV_U32 boardId, i;
MV_U32 indexFound = 0;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("%s: unknown board ID '%u'\n", __func__, boardId);
return MV_ERROR;
}
for (i = 0; i < BOARD_INFO(boardId)->numBoardGppInfo; i++) {
if (BOARD_INFO(boardId)->pBoardGppInfo[i].devClass == gppClass) {
if (indexFound == index) {
if (pinNum)
*pinNum = BOARD_INFO(boardId)->pBoardGppInfo[i].gppPinNum;
if (polarity)
*polarity = !BOARD_INFO(boardId)->pBoardGppInfo[i].activeLow;
return MV_OK;
}
indexFound++;
}
}
return MV_ERROR;
}
/*******************************************************************************
* mvBoardReset - mvBoardReset
*
* DESCRIPTION:
* Reset the board
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* None
*
*******************************************************************************/
MV_VOID mvBoardReset(MV_VOID)
{
MV_32 resetPin;
/* Get gpp reset pin if define */
resetPin = mvBoardResetGpioPinGet();
if (resetPin != MV_ERROR) {
MV_REG_BIT_RESET(GPP_DATA_OUT_REG(0), (1 << resetPin));
MV_REG_BIT_RESET(GPP_DATA_OUT_EN_REG(0), (1 << resetPin));
} else {
/* No gpp reset pin was found, try to reset ussing
** system reset out */
MV_REG_BIT_SET(CPU_RSTOUTN_MASK_REG, BIT2);
MV_REG_BIT_SET(CPU_SYS_SOFT_RST_REG, BIT0);
}
}
/*******************************************************************************
* mvBoardResetGpioPinGet - mvBoardResetGpioPinGet
*
* DESCRIPTION:
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* GPIO pin number. The function return -1 for bad parameters.
*
*******************************************************************************/
MV_32 mvBoardResetGpioPinGet(MV_VOID)
{
return mvBoarGpioPinNumGet(BOARD_GPP_RESET, 0);
}
/*******************************************************************************
* mvBoardSDIOGpioPinGet - mvBoardSDIOGpioPinGet
*
* DESCRIPTION:
* used for hotswap detection
* INPUT:
* type - Type of SDIO GPP to get.
*
* OUTPUT:
* None.
*
* RETURN:
* GPIO pin number. The function return -1 for bad parameters.
*
*******************************************************************************/
MV_32 mvBoardSDIOGpioPinGet(MV_BOARD_GPP_CLASS type)
{
if ((type != BOARD_GPP_SDIO_POWER) && (type != BOARD_GPP_SDIO_DETECT) && (type != BOARD_GPP_SDIO_WP))
return MV_FAIL;
return mvBoarGpioPinNumGet(type, 0);
}
/*******************************************************************************
* mvBoardUSBVbusGpioPinGet - return Vbus input GPP
*
* DESCRIPTION:
*
* INPUT:
* int devNo.
*
* OUTPUT:
* None.
*
* RETURN:
* GPIO pin number. The function return -1 for bad parameters.
*
*******************************************************************************/
MV_32 mvBoardUSBVbusGpioPinGet(MV_32 devId)
{
return mvBoarGpioPinNumGet(BOARD_GPP_USB_VBUS, devId);
}
/*******************************************************************************
* mvBoardUSBVbusEnGpioPinGet - return Vbus Enable output GPP
*
* DESCRIPTION:
*
* INPUT:
* int devNo.
*
* OUTPUT:
* None.
*
* RETURN:
* GPIO pin number. The function return -1 for bad parameters.
*
*******************************************************************************/
MV_32 mvBoardUSBVbusEnGpioPinGet(MV_32 devId)
{
return mvBoarGpioPinNumGet(BOARD_GPP_USB_VBUS_EN, devId);
}
/*******************************************************************************
* mvBoardGpioIntMaskGet - Get GPIO mask for interrupt pins
*
* DESCRIPTION:
* This function returns a 32-bit mask of GPP pins that connected to
* interrupt generating sources on board.
* For example if UART channel A is hardwired to GPP pin 8 and
* UART channel B is hardwired to GPP pin 4 the fuinction will return
* the value 0x000000110
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* See description. The function return -1 if board is not identified.
*
*******************************************************************************/
MV_U32 mvBoardGpioIntMaskGet(MV_U32 gppGrp)
{
MV_U32 boardId;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardGpioIntMaskGet:Board unknown.\n");
return MV_ERROR;
}
switch (gppGrp) {
case (0):
return BOARD_INFO(boardId)->intsGppMaskLow;
break;
case (1):
return BOARD_INFO(boardId)->intsGppMaskMid;
break;
case (2):
return BOARD_INFO(boardId)->intsGppMaskHigh;
break;
default:
return MV_ERROR;
}
}
/*******************************************************************************
* mvBoardMppGet - Get board dependent MPP register value
*
* DESCRIPTION:
* MPP settings are derived from board design.
* MPP group consist of 8 MPPs. An MPP group represent MPP
* control register.
* This function retrieves board dependend MPP register value.
*
* INPUT:
* mppGroupNum - MPP group number.
*
* OUTPUT:
* None.
*
* RETURN:
* 32bit value describing MPP control register value.
*
*******************************************************************************/
MV_32 mvBoardMppGet(MV_U32 mppGroupNum)
{
MV_U32 boardId;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardMppGet:Board unknown.\n");
return MV_ERROR;
}
return BOARD_INFO(boardId)->pBoardMppConfigValue[0].mppGroup[mppGroupNum];
}
/*******************************************************************************
* mvBoardEthComplexConfigGet - Return ethernet complex board configuration.
*
* DESCRIPTION:
* Returns the ethernet / Sata complex configuration from the board spec
* structure.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* 32bit value describing the ethernet complex config.
*
*******************************************************************************/
MV_U32 mvBoardEthComplexConfigGet(MV_VOID)
{
MV_U32 boardId;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardEthComplexConfigGet: Board unknown.\n");
return MV_ERROR;
}
return BOARD_INFO(boardId)->pBoardMppTypeValue->ethSataComplexOpt;
}
/*******************************************************************************
* mvBoardEthComplexConfigSet - Set ethernet complex board configuration.
*
* DESCRIPTION:
* Sets the ethernet / Sata complex configuration in the board spec
* structure.
*
* INPUT:
* ethConfig - 32bit value describing the ethernet complex config.
*
* OUTPUT:
* None.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_VOID mvBoardEthComplexConfigSet(MV_U32 ethConfig)
{
MV_U32 boardId;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardEthComplexConfigSet: Board unknown.\n");
return;
}
/* Set ethernet complex configuration. */
BOARD_INFO(boardId)->pBoardMppTypeValue->ethSataComplexOpt = ethConfig;
if ((boardId != DB_88F6601_BP_ID) && (boardId != RD_88F6601_MC_ID)
&& (boardId != GFLT200_ID) && (boardId != GFLT110_ID))
{ /* KW2 only */
/* Update link speed for MAC0 / 1 */
/* If MAC 0 is connected to switch, then set to speed 1000Mbps */
if (mvBoardIsInternalSwitchConnected(0))
BOARD_INFO(boardId)->pBoardMacInfo[0].boardMacSpeed = BOARD_MAC_SPEED_1000M;
if (mvBoardIsInternalSwitchConnected(1))
BOARD_INFO(boardId)->pBoardMacInfo[1].boardMacSpeed = BOARD_MAC_SPEED_1000M;
}
return;
}
/*******************************************************************************
* mvBoardPonConfigGet
*
* DESCRIPTION:
* Returns the PON port configuration from the board spec structure.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* 32bit value describing the PON port configuration.
*
*****************************************************************************/
MV_U32 mvBoardPonConfigGet(MV_VOID)
{
MV_U32 boardId;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardPonConfigGet:Board unknown.\n");
return MV_ERROR;
}
return BOARD_INFO(boardId)->ponConfigValue;
}
/*******************************************************************************
* mvBoardPonConfigSet
*
* DESCRIPTION:
* Set the PON port configuration from the board spec structure.
*
* INPUT:
* ponConfig - 32bit value describing the PON port configuration.
*
* OUTPUT:
* None.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_VOID mvBoardPonConfigSet(MV_U32 ponConfig)
{
MV_U32 boardId;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardPonConfigSet:Board unknown.\n");
return;
}
BOARD_INFO(boardId)->ponConfigValue = ponConfig;
return;
}
/*******************************************************************************
* mvBoardGppConfigGet
*
* DESCRIPTION:
* Get board configuration according to the input configuration GPP's.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* The value of the board configuration GPP's.
*
*******************************************************************************/
MV_U32 mvBoardGppConfigGet(MV_VOID)
{
MV_U32 boardId, i;
MV_U32 result = 0;
MV_U32 gpp;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardGppConfigGet: Board unknown.\n");
return 0;
}
for (i = 0; i < BOARD_INFO(boardId)->numBoardGppInfo; i++) {
if (BOARD_INFO(boardId)->pBoardGppInfo[i].devClass == BOARD_GPP_CONF) {
gpp = BOARD_INFO(boardId)->pBoardGppInfo[i].gppPinNum;
result <<= 1;
result |= (mvGppValueGet(gpp >> 5, 1 << (gpp & 0x1F)) >> (gpp & 0x1F));
}
}
return result;
}
/*******************************************************************************
* mvBoardModuleConfigSet
*
* DESCRIPTION:
* Set modules scan result, in order to skip scanning opration if needed.
*
* INPUT:
* modConfig - Bitmask including the scan result of the ethernet complex
* and the TDM modules.
*
* OUTPUT:
* None.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_VOID mvBoardModuleConfigSet(MV_U32 modConfig)
{
mvBoardStaticModuleConfig = MV_TRUE;
mvBoardModuleConfig = modConfig;
return;
}
/*******************************************************************************
* mvBoardModuleConfigGet
*
* DESCRIPTION:
* Get modules scan result.
*
* INPUT:
* None.
*
* OUTPUT:
* modConfig - Bitmask including the scan result of the ethernet complex
* and the TDM modules.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_VOID mvBoardModuleConfigGet(MV_U32 *modConfig)
{
MV_U32 ethCompCfg;
MV_8 tdmCfg;
MV_U32 boardId = mvBoardIdGet();
ethCompCfg = mvBoardEthComplexConfigGet();
tdmCfg = BOARD_INFO(boardId)->boardTdmInfoIndex;
*modConfig = MV_BRD_MODULE_CFG_BUILD(ethCompCfg, tdmCfg);
return;
}
/*******************************************************************************
* mvBoardMppIdUpdate - Update MPP ID's according to modules auto-detection.
*
* DESCRIPTION:
* Update MPP ID's according to on-board modules as detected using TWSI bus.
*
* INPUT:
* ethSrc - Sources for the rgmiiA & fe/Ge interfaces. might be needed in
* case where modules detection is not sufficient to configure
* internal Mux'es.
*
* OUTPUT:
* None.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_VOID mvBoardMppIdUpdate(MV_VOID)
{
MV_U32 devId;
MV_U32 ethComplexOpt;
MV_U32 brdModules = 0;
MV_U32 ethConfig;
MV_U32 ponOpt;
MV_ETH_COMPLEX_IF_SOURCES ethCfgSrc;
devId = mvCtrlModelGet();
/* Setup ethernet / sata complex configuration. */
ethComplexOpt = mvBoardEthComplexConfigGet();
if (ethComplexOpt == ESC_OPT_AUTO) {
if (mvBoardStaticModuleConfig == MV_FALSE) {
mvBoardEthSataModulesScan(&brdModules, &ethCfgSrc);
mvCtrlEthSataComplexBuildConfig(brdModules, &ethCfgSrc, &ethConfig);
} else {
ethConfig = MV_BRD_MODULE_CFG_ETH_GET(mvBoardModuleConfig);
}
mvBoardEthComplexConfigSet(ethConfig);
mvBoardSwitchInfoUpdate();
} else if (mvBoardIdGet() == RD_88F6560_GW_ID) {
/* Check the board configuration GPP's to see if Sata port is
** enabled.
*/
if (mvBoardGppConfigGet() == 1) {
ethConfig = mvBoardEthComplexConfigGet();
ethConfig &= ~ESC_OPT_QSGMII;
ethConfig |= (ESC_OPT_SATA | ESC_OPT_FE3PHY);
mvBoardEthComplexConfigSet(ethConfig);
}
}
/* Setup TDM configuration. */
if (MV_6601_DEV_ID == devId){
MV_U32 boardId = mvBoardIdGet();
if (brdModules & MV_BOARD_MODULE_TDM_1_ID) {
/* Perform scan only for DB board. */
if (!mvBoardModuleAutoDetectEnabled())
BOARD_INFO(boardId)->boardTdmInfoIndex = -1; /* We have only a single Slic config for RD boards. */
else
BOARD_INFO(boardId)->boardTdmInfoIndex = BOARD_TDM_SLIC_880;
} else {
BOARD_INFO(boardId)->boardTdmInfoIndex = -1; /* no TDM */
BOARD_INFO(boardId)->numBoardTdmInfo[BOARD_TDM_SLIC_880] = 0;
}
} else {
mvBoardTdmModulesScan();
/* Setup xPON complex configuration */
ponOpt = mvBoardPonConfigGet();
if (ponOpt == BOARD_PON_AUTO) {
mvBoardPonModulesScan(&ponOpt);
mvBoardPonConfigSet(ponOpt);
}
}
ethConfig = mvBoardEthComplexConfigGet();
if (MV_6601_DEV_ID == devId){
if (ethConfig & ESC_OPT_GEPHY_MAC0) {
mvBoardPhyAddrSet(0,0);
mvBoardPhyAddrSet(1,1);
}
else {
mvBoardPhyAddrSet(0,1);
mvBoardPhyAddrSet(1,0x1f);
}
}
/* Update MPP output voltage for RGMIIB & RGMII2 to 1.8V */
if (ethConfig & (ESC_OPT_RGMIIA_MAC0 | ESC_OPT_RGMIIA_MAC1 | ESC_OPT_RGMIIA_SW_P5 | ESC_OPT_RGMIIA_SW_P6)) {
/* Set GE_A & GE_B output voltage to 1.8V */
MV_REG_BIT_SET(MPP_OUTPUT_DRIVE_REG, MPP_GE_A_1_8_OUTPUT_DRIVE | MPP_GE_B_1_8_OUTPUT_DRIVE);
} else if (ethConfig & ESC_OPT_RGMIIB_MAC0) {
/* Set GE_A output voltage to 1.8V */
MV_REG_BIT_SET(MPP_OUTPUT_DRIVE_REG, MPP_GE_B_1_8_OUTPUT_DRIVE);
}
#if defined(CONFIG_MV_ETH_LEGACY)
{
MV_U32 portMode;
/* Set port to MII for MII module */
portMode = mvBoardEthPortsModeGet();
ethConfig = mvBoardEthComplexConfigGet();
if ((ethConfig & ESC_OPT_RGMIIA_MAC1) && (!(portMode & EPM_MAC1_MII)))
mvEthGmacRgmiiSet(1, 1);
if ((ethConfig & (ESC_OPT_RGMIIB_MAC0 | ESC_OPT_RGMIIA_MAC0)) &&
(!(portMode & EPM_MAC0_MII)))
mvEthGmacRgmiiSet(0, 1);
if (ethConfig & ESC_OPT_MAC0_2_SW_P4)
mvEthGmacRgmiiSet(0, 0);
if (ethConfig & (ESC_OPT_GEPHY_MAC1 | ESC_OPT_MAC1_2_SW_P5))
mvEthGmacRgmiiSet(1, 0);
}
#endif /* CONFIG_MV_ETH_LEGACY */
return;
}
/*******************************************************************************
* mvBoardMppGroupTypeGet
*
* DESCRIPTION:
*
* INPUT:
* mppGroupClass - MPP group number 0 for MPP[35:20] or 1 for MPP[49:36].
*
* OUTPUT:
* None.
*
* RETURN:
*
*******************************************************************************/
MV_BOARD_MPP_TYPE_CLASS mvBoardMppGroupTypeGet(MV_BOARD_MPP_GROUP_CLASS mppGroupClass)
{
MV_U32 boardId;
MV_U32 ethCompCfg;
MV_BOARD_MPP_TYPE_CLASS result = MV_BOARD_OTHER;
boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardMppGet:Board unknown.\n");
return MV_ERROR;
}
if (!mvBoardModuleAutoDetectEnabled())
return MV_BOARD_OTHER;
switch (mppGroupClass) {
case (MV_BOARD_MPP_GROUP_1):
/* Get TDM / TDU MPP type. */
#ifdef MV_INCLUDE_TDM
if (mvBoardTdmDevicesCountGet() > 0) {
if (mvCtrlTdmUnitTypeGet() == TDM_2CH_UNIT_ID)
result = MV_BOARD_TDM_2CH;
else
result = MV_BOARD_TDM_32CH;
}
#endif
break;
case (MV_BOARD_MPP_GROUP_2):
/* Get GE0 MPP type. */
ethCompCfg = BOARD_INFO(boardId)->pBoardMppTypeValue->ethSataComplexOpt;
if (ethCompCfg & ESC_OPT_RGMIIB_MAC0)
result = MV_BOARD_GE0;
if (result == MV_BOARD_OTHER) {
#ifdef MV_INCLUDE_TDM
/* Get TDM / TDU MPP type. */
if ((mvBoardTdmDevicesCountGet() > 0) && (mvCtrlTdmUnitTypeGet() == TDM_32CH_UNIT_ID))
result = MV_BOARD_TDM_32CH;
#endif
}
break;
case (MV_BOARD_MPP_GROUP_3):
/* Get GE0 / GE1 / SW_P5 MPP type. */
ethCompCfg = BOARD_INFO(boardId)->pBoardMppTypeValue->ethSataComplexOpt;
if (ethCompCfg & ESC_OPT_RGMIIA_MAC0)
result = MV_BOARD_GE0;
else if (ethCompCfg & ESC_OPT_RGMIIA_MAC1)
result = MV_BOARD_GE1;
else if (ethCompCfg & ESC_OPT_RGMIIA_SW_P5)
result = MV_BOARD_SW_P5;
else if (ethCompCfg & ESC_OPT_RGMIIA_SW_P6)
result = MV_BOARD_SW_P6;
else
result = MV_BOARD_OTHER;
break;
default:
break;
}
return result;
}
/*******************************************************************************
* mvBoardTdmSpiModeGet - return SLIC/DAA connection
*
* DESCRIPTION:
*
* INPUT:
*
* OUTPUT:
* None.
*
* RETURN:
*
*******************************************************************************/
MV_32 mvBoardTdmSpiModeGet(MV_VOID)
{
return DUAL_CHIP_SELECT_MODE;
}
/*******************************************************************************
* mvBoardTdmDevicesCountGet
*
* DESCRIPTION:
* Return the number of TDM devices on board.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* Number of devices.
*
*******************************************************************************/
MV_U8 mvBoardTdmDevicesCountGet(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
MV_8 index;
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardTdmDevicesCountGet: Board unknown.\n");
return 0;
}
index = BOARD_INFO(boardId)->boardTdmInfoIndex;
if (index == (MV_8)-1)
return 0;
return BOARD_INFO(boardId)->numBoardTdmInfo[(MV_U8)index];
}
/*******************************************************************************
* mvBoardTdmSpiCsGet
*
* DESCRIPTION:
* Return the SPI Chip-select number for a given device.
*
* INPUT:
* devId - The Slic device ID to get the SPI CS for.
*
* OUTPUT:
* None.
*
* RETURN:
* The SPI CS if found, -1 otherwise.
*
*******************************************************************************/
MV_U8 mvBoardTdmSpiCsGet(MV_U8 devId)
{
MV_U32 boardId = mvBoardIdGet();
MV_8 index;
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardTdmDevicesCountGet: Board unknown.\n");
return -1;
}
index = BOARD_INFO(boardId)->boardTdmInfoIndex;
if (index == (MV_8)-1)
return 0;
if (devId >= BOARD_INFO(boardId)->numBoardTdmInfo[(MV_U8)index])
return -1;
return BOARD_INFO(boardId)->pBoardTdmInt2CsInfo[(MV_U8)index][devId].spiCs;
}
/*******************************************************************************
* mvBoardTdmSpiIdGet
*
* DESCRIPTION:
* Return SPI port ID per board.
*
* INPUT:
* None
*
* OUTPUT:
* None.
*
* RETURN:
* SPI port ID.
*
*******************************************************************************/
MV_U8 mvBoardTdmSpiIdGet(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardTdmSpiIdGet: Board unknown.\n");
return -1;
}
return BOARD_INFO(boardId)->pBoardTdmSpiInfo[0].spiId;
}
/*******************************************************************************
* mvBoardModuleTypePrint
*
* DESCRIPTION:
* Print on-board detected modules.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* None.
*
*******************************************************************************/
MV_VOID mvBoardMppModuleTypePrint(MV_VOID)
{
MV_U32 ethConfig;
MV_U32 ponOpt;
mvOsOutput("Modules Detected:\n");
/* GPON / EPON */
ponOpt = mvBoardPonConfigGet();
if (ponOpt == BOARD_EPON_CONFIG)
mvOsOutput(" EPON module detected.\n");
else if (ponOpt == BOARD_GPON_CONFIG)
mvOsOutput(" GPON module detected.\n");
else
mvOsOutput(" No PON module.\n");
/* TDM */
if (mvBoardTdmDevicesCountGet() > 0)
mvOsOutput(" TDM module.\n");
ethConfig = mvBoardEthComplexConfigGet();
if (ethConfig & ESC_OPT_ILLEGAL) {
mvOsOutput(" Illegal configuration detected!\n");
return;
}
/* Sata */
if (ethConfig & ESC_OPT_SATA)
mvOsOutput(" Sata module detected.\n");
/* Ethernet Complex */
/* RGMIIA */
if (ethConfig & ESC_OPT_RGMIIA_MAC0)
mvOsOutput(" RGMIIA Module on MAC0.\n");
if (ethConfig & ESC_OPT_RGMIIA_MAC1)
mvOsOutput(" RGMIIA Module on MAC1.\n");
if (ethConfig & ESC_OPT_RGMIIA_SW_P5)
mvOsOutput(" RGMIIA Module on Switch port #5.\n");
if (ethConfig & ESC_OPT_RGMIIA_SW_P6)
mvOsOutput(" RGMIIA Module on Switch port #6.\n");
/* RGMIIB */
if (ethConfig & ESC_OPT_RGMIIB_MAC0)
mvOsOutput(" RGMIIB Module on MAC0.\n");
/* Ethernet Switch */
if (ethConfig & (ESC_OPT_MAC0_2_SW_P4 | ESC_OPT_MAC1_2_SW_P5)) {
if (ethConfig & ESC_OPT_MAC0_2_SW_P4)
mvOsOutput(" Ethernet Switch on MAC0.\n");
if (ethConfig & ESC_OPT_MAC1_2_SW_P5)
mvOsOutput(" Ethernet Switch on MAC1\n");
if (mvBoardSmiScanModeGet(0) == 1)
mvOsOutput(" Switch in Single-Chip Address Mode.\n");
}
/* 3xFE PHY */
if (ethConfig & ESC_OPT_FE3PHY)
mvOsOutput(" 3xFE PHY Module.\n");
/* Internal FE/GE Phy */
if (DB_88F6601_BP_ID == mvBoardIdGet()) {
if (ethConfig & ESC_OPT_GEPHY_MAC0) {
mvOsOutput(" GE-PHY on MAC0.\n");
mvOsOutput(" LP SERDES on MAC1.\n");
}
else {
mvOsOutput(" LP SERDES on MAC0.\n");
mvOsOutput(" MAC1 disconnected.\n");
}
/* LP SERDES for DB 6601 */
if (ethConfig & ESC_OPT_LP_SERDES_FE_GE_PHY)
mvOsOutput(" LP SERDES connected to external PHY.\n");
else
mvOsOutput(" LP SERDES connected to SFP.\n");
/* SERDES speed */
mvOsOutput(" LP SERDES configured at %sGbps\n",
(ethConfig & ESC_OPT_SGMII_2_5)?"2.5":"1");
return;
}
else if (ethConfig & (ESC_OPT_GEPHY_MAC0 | ESC_OPT_GEPHY_MAC1 | ESC_OPT_GEPHY_SW_P0 | ESC_OPT_GEPHY_SW_P5 )) {
if (ethConfig & ESC_OPT_GEPHY_MAC0)
mvOsOutput(" GE-PHY on MAC0.\n");
if (ethConfig & ESC_OPT_GEPHY_MAC1)
mvOsOutput(" GE-PHY on MAC1.\n");
if (ethConfig & ESC_OPT_GEPHY_SW_P0)
mvOsOutput(" GE-PHY on Switch port #0.\n");
if (ethConfig & ESC_OPT_GEPHY_SW_P5)
mvOsOutput(" GE-PHY on Switch port #5.\n");
}
/* QSGMII */
if (ethConfig & ESC_OPT_QSGMII)
mvOsOutput(" QSGMII Module.\n");
/* SGMII */
if (ethConfig & ESC_OPT_SGMII) {
if (ethConfig & ESC_OPT_SGMII_2_SW_P1)
mvOsOutput(" SGMII Module on Switch port #1.\n");
else
mvOsOutput(" SGMII Module on MAC0.\n");
}
/* SGMII-2.5G */
if (ethConfig & ESC_OPT_SGMII_2_5)
mvOsOutput(" SGMII-2.5G Module.\n");
return;
}
/*******************************************************************************
* mvBoardIsGbEPortConnected
*
* DESCRIPTION:
* Checks if a given GbE port is actually connected to the GE-PHY, internal Switch or any RGMII module.
*
* INPUT:
* port - GbE port number (0 or 1).
*
* OUTPUT:
* None.
*
* RETURN:
* MV_TRUE if port is connected, MV_FALSE otherwise.
*
*******************************************************************************/
MV_BOOL mvBoardIsGbEPortConnected(MV_U32 ethPortNum)
{
MV_U32 ethConfig;
ethConfig = mvBoardEthComplexConfigGet();
if (ethConfig & ESC_OPT_ILLEGAL)
return MV_FALSE;
if (DB_88F6601_BP_ID == mvBoardIdGet()) {
if (ethPortNum == 0)
return MV_TRUE;
if (ethConfig & ESC_OPT_GEPHY_MAC0)
return MV_TRUE;
return MV_FALSE;
}
if ((RD_88F6601_MC_ID == mvBoardIdGet())
|| (GFLT400_ID == mvBoardIdGet()) || (GFLT300_ID == mvBoardIdGet())
|| (GFLT200_ID == mvBoardIdGet()) || (GFLT110_ID == mvBoardIdGet())) {
if (ethPortNum == 0)
return MV_TRUE;
return MV_FALSE;
}
if (ethPortNum == 0) {
if (ethConfig & (ESC_OPT_RGMIIA_MAC0 | ESC_OPT_RGMIIB_MAC0 | ESC_OPT_MAC0_2_SW_P4))
return MV_TRUE;
else
return MV_FALSE;
}
if (ethPortNum == 1) {
if (ethConfig & (ESC_OPT_RGMIIA_MAC1 | ESC_OPT_MAC1_2_SW_P5 | ESC_OPT_GEPHY_MAC1))
return MV_TRUE;
else
return MV_FALSE;
}
mvOsPrintf("mvBoardIsGbEPortConnected: unknown port %d\n", ethPortNum);
return MV_FALSE;
}
/* Board devices API managments */
/*******************************************************************************
* mvBoardGetDeviceNumber - Get number of device of some type on the board
*
* DESCRIPTION:
*
* INPUT:
* devType - The device type ( Flash,RTC , etc .. )
*
* OUTPUT:
* None.
*
* RETURN:
* If the device is found on the board the then the functions returns the
* number of those devices else the function returns 0
*
*
*******************************************************************************/
MV_32 mvBoardGetDevicesNumber(MV_BOARD_DEV_CLASS devClass)
{
MV_U32 foundIndex = 0, devNum;
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("mvBoardGetDeviceNumber:Board unknown.\n");
return 0xFFFFFFFF;
}
for (devNum = START_DEV_CS; devNum < BOARD_INFO(boardId)->numBoardDeviceIf; devNum++) {
if (BOARD_INFO(boardId)->pDevCsInfo[devNum].devClass == devClass)
foundIndex++;
}
return foundIndex;
}
/*******************************************************************************
* mvBoardGetDeviceBaseAddr - Get base address of a device existing on the board
*
* DESCRIPTION:
*
* INPUT:
* devIndex - The device sequential number on the board
* devType - The device type ( Flash,RTC , etc .. )
*
* OUTPUT:
* None.
*
* RETURN:
* If the device is found on the board the then the functions returns the
* Base address else the function returns 0xffffffff
*
*
*******************************************************************************/
MV_32 mvBoardGetDeviceBaseAddr(MV_32 devNum, MV_BOARD_DEV_CLASS devClass)
{
MV_DEV_CS_INFO *devEntry;
devEntry = boardGetDevEntry(devNum, devClass);
if (devEntry != NULL)
return mvCpuIfTargetWinBaseLowGet(DEV_TO_TARGET(devEntry->deviceCS));
return 0xFFFFFFFF;
}
/*******************************************************************************
* mvBoardGetDeviceBusWidth - Get Bus width of a device existing on the board
*
* DESCRIPTION:
*
* INPUT:
* devIndex - The device sequential number on the board
* devType - The device type ( Flash,RTC , etc .. )
*
* OUTPUT:
* None.
*
* RETURN:
* If the device is found on the board the then the functions returns the
* Bus width else the function returns 0xffffffff
*
*
*******************************************************************************/
MV_32 mvBoardGetDeviceBusWidth(MV_32 devNum, MV_BOARD_DEV_CLASS devClass)
{
MV_DEV_CS_INFO *devEntry;
devEntry = boardGetDevEntry(devNum, devClass);
if (devEntry != NULL)
return devEntry->devWidth;
return 0xFFFFFFFF;
}
/*******************************************************************************
* mvBoardGetDeviceWidth - Get dev width of a device existing on the board
*
* DESCRIPTION:
*
* INPUT:
* devIndex - The device sequential number on the board
* devType - The device type ( Flash,RTC , etc .. )
*
* OUTPUT:
* None.
*
* RETURN:
* If the device is found on the board the then the functions returns the
* dev width else the function returns 0xffffffff
*
*
*******************************************************************************/
MV_32 mvBoardGetDeviceWidth(MV_32 devNum, MV_BOARD_DEV_CLASS devClass)
{
MV_DEV_CS_INFO *devEntry;
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("Board unknown.\n");
return 0xFFFFFFFF;
}
devEntry = boardGetDevEntry(devNum, devClass);
if (devEntry != NULL)
return devEntry->devWidth;
return MV_ERROR;
}
/*******************************************************************************
* mvBoardGetDeviceWinSize - Get the window size of a device existing on the board
*
* DESCRIPTION:
*
* INPUT:
* devIndex - The device sequential number on the board
* devType - The device type ( Flash,RTC , etc .. )
*
* OUTPUT:
* None.
*
* RETURN:
* If the device is found on the board the then the functions returns the
* window size else the function returns 0xffffffff
*
*
*******************************************************************************/
MV_32 mvBoardGetDeviceWinSize(MV_32 devNum, MV_BOARD_DEV_CLASS devClass)
{
MV_DEV_CS_INFO *devEntry;
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("Board unknown.\n");
return 0xFFFFFFFF;
}
devEntry = boardGetDevEntry(devNum, devClass);
if (devEntry != NULL)
return mvCpuIfTargetWinSizeGet(DEV_TO_TARGET(devEntry->deviceCS));
return 0xFFFFFFFF;
}
/*******************************************************************************
* boardGetDevEntry - returns the entry pointer of a device on the board
*
* DESCRIPTION:
*
* INPUT:
* devIndex - The device sequential number on the board
* devType - The device type ( Flash,RTC , etc .. )
*
* OUTPUT:
* None.
*
* RETURN:
* If the device is found on the board the then the functions returns the
* dev number else the function returns 0x0
*
*******************************************************************************/
static MV_DEV_CS_INFO *boardGetDevEntry(MV_32 devNum, MV_BOARD_DEV_CLASS devClass)
{
MV_U32 foundIndex = 0, devIndex;
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("boardGetDevEntry: Board unknown.\n");
return NULL;
}
for (devIndex = START_DEV_CS; devIndex < BOARD_INFO(boardId)->numBoardDeviceIf; devIndex++) {
if (BOARD_INFO(boardId)->pDevCsInfo[devIndex].devClass == devClass) {
if (foundIndex == devNum)
return &(BOARD_INFO(boardId)->pDevCsInfo[devIndex]);
foundIndex++;
}
}
/* device not found */
return NULL;
}
/*******************************************************************************
* boardGetDevCSNum
*
* DESCRIPTION:
* Return the device's chip-select number.
*
* INPUT:
* devIndex - The device sequential number on the board
* devType - The device type ( Flash,RTC , etc .. )
*
* OUTPUT:
* None.
*
* RETURN:
* If the device is found on the board the then the functions returns the
* dev number else the function returns 0x0
*
*******************************************************************************/
MV_U32 boardGetDevCSNum(MV_32 devNum, MV_BOARD_DEV_CLASS devClass)
{
MV_DEV_CS_INFO *devEntry;
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("Board unknown.\n");
return 0xFFFFFFFF;
}
devEntry = boardGetDevEntry(devNum, devClass);
if (devEntry != NULL)
return devEntry->deviceCS;
return 0xFFFFFFFF;
}
/*******************************************************************************
* mvBoardTwsiAddrTypeGet -
*
* DESCRIPTION:
* Return the TWSI address type for a given twsi device class.
*
* INPUT:
* twsiClass - The TWSI device to return the address type for.
* index - The TWSI device index (Pass 0 in case of a single
* device)
*
* OUTPUT:
* None.
*
* RETURN:
* The TWSI address type.
*
*******************************************************************************/
MV_U8 mvBoardTwsiAddrTypeGet(MV_BOARD_TWSI_CLASS twsiClass, MV_U32 index)
{
int i;
MV_U32 indexFound = 0;
MV_U32 boardId = mvBoardIdGet();
for (i = 0; i < BOARD_INFO(boardId)->numBoardTwsiDev; i++) {
if (BOARD_INFO(boardId)->pBoardTwsiDev[i].devClass == twsiClass) {
if (indexFound == index)
return BOARD_INFO(boardId)->pBoardTwsiDev[i].twsiDevAddrType;
indexFound++;
}
}
return (MV_ERROR);
}
/*******************************************************************************
* mvBoardTwsiAddrGet -
*
* DESCRIPTION:
* Return the TWSI address for a given twsi device class.
*
* INPUT:
* twsiClass - The TWSI device to return the address type for.
* index - The TWSI device index (Pass 0 in case of a single
* device)
*
* OUTPUT:
* None.
*
* RETURN:
* The TWSI address.
*
*******************************************************************************/
MV_U8 mvBoardTwsiAddrGet(MV_BOARD_TWSI_CLASS twsiClass, MV_U32 index)
{
int i;
MV_U32 indexFound = 0;
MV_U32 boardId = mvBoardIdGet();
for (i = 0; i < BOARD_INFO(boardId)->numBoardTwsiDev; i++) {
if (BOARD_INFO(boardId)->pBoardTwsiDev[i].devClass == twsiClass) {
if (indexFound == index)
return BOARD_INFO(boardId)->pBoardTwsiDev[i].twsiDevAddr;
indexFound++;
}
}
return (0xFF);
}
/*******************************************************************************
* mvBoardNandWidthGet -
*
* DESCRIPTION: Get the width of the first NAND device in byte.
*
* INPUT:
*
* OUTPUT:
* None.
*
* RETURN: 1, 2, 4 or MV_ERROR
*
*
*******************************************************************************/
MV_32 mvBoardNandWidthGet(MV_VOID)
{
MV_U32 devNum;
MV_U32 devWidth;
MV_U32 boardId = mvBoardIdGet();
for (devNum = START_DEV_CS; devNum < BOARD_INFO(boardId)->numBoardDeviceIf; devNum++) {
devWidth = mvBoardGetDeviceWidth(devNum, BOARD_DEV_NAND_FLASH);
if (devWidth != MV_ERROR)
return (devWidth / 8);
}
/* NAND wasn't found */
return MV_ERROR;
}
MV_U32 gBoardId = -1;
/*******************************************************************************
* mvBoardIdGet - Get Board model
*
* DESCRIPTION:
* This function returns board ID.
* Board ID is 32bit word constructed of board model (16bit) and
* board revision (16bit) in the following way: 0xMMMMRRRR.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* 32bit board ID number, '-1' if board is undefined.
*
*******************************************************************************/
MV_U32 mvBoardIdGet(MV_VOID)
{
MV_U32 tmpBoardId = -1;
if (gBoardId == -1) {
#if defined(DB_88F6500)
tmpBoardId = DB_88F6535_BP_ID;
#elif defined(RD_88F6510)
tmpBoardId = RD_88F6510_SFU_ID;
#elif defined(RD_88F6530)
tmpBoardId = RD_88F6530_MDU_ID;
#elif defined(RD_88F6560)
tmpBoardId = RD_88F6560_GW_ID;
#elif defined(DB_88F6560_PCAC)
tmpBoardId = DB_88F6560_PCAC_ID;
#elif defined(DB_88F6601)
tmpBoardId = DB_88F6601_BP_ID;
#elif defined(RD_88F6601)
tmpBoardId = RD_88F6601_MC_ID;
#elif defined(DB_CUSTOMER)
tmpBoardId = DB_CUSTOMER_ID;
#elif defined(GFLT200)
tmpBoardId = GFLT200_ID;
#elif defined(GFLT400)
tmpBoardId = GFLT400_ID;
#elif defined(GFLT110)
if (MV_REG_READ(MV_GPP_REGS_OFFSET_0 + 0x10 ) & BIT15)
tmpBoardId = GFLT110_ID;
else
tmpBoardId = GFLT300_ID;
#endif
gBoardId = tmpBoardId;
}
return gBoardId;
}
MV_BOARD_INFO *mvBoardInfoGet(MV_VOID)
{
MV_U32 boardId = mvBoardIdGet();
if (!((boardId >= BOARD_ID_BASE) && (boardId < MV_MAX_BOARD_ID))) {
mvOsPrintf("Board unknown.\n");
return NULL;
}
return BOARD_INFO(boardId);
}
/*******************************************************************************
* mvBoardTwsiSatRGet -
*
* DESCRIPTION:
*
* INPUT:
* device num - one of three devices
* reg num - 0 or 1
*
* OUTPUT:
* None.
*
* RETURN:
* reg value
*
*******************************************************************************/
MV_U8 mvBoardTwsiSatRGet(MV_U8 devNum, MV_U8 regNum)
{
MV_TWSI_SLAVE twsiSlave;
MV_TWSI_ADDR slave;
MV_U8 data;
/* TWSI init */
slave.type = ADDR7_BIT;
slave.address = 0;
mvTwsiInit(0, TWSI_SPEED, mvBoardTclkGet(), &slave, 0);
/* Read MPP module ID */
DB(mvOsPrintf("Board: Read S@R device read\n"));
twsiSlave.slaveAddr.address = mvBoardTwsiAddrGet(BOARD_DEV_TWSI_SATR, devNum);
twsiSlave.slaveAddr.type = mvBoardTwsiAddrTypeGet(BOARD_DEV_TWSI_SATR, devNum);
twsiSlave.validOffset = MV_TRUE;
/* Use offset as command */
twsiSlave.offset = regNum;
twsiSlave.moreThen256 = MV_FALSE;
if (MV_OK != mvTwsiRead(0, &twsiSlave, &data, 1)) {
DB(mvOsPrintf("Board: Read S@R fail\n"));
return MV_ERROR;
}
DB(mvOsPrintf("Board: Read S@R succeded\n"));
return data;
}
/*******************************************************************************
* mvBoardTwsiSatRSet -
*
* DESCRIPTION:
*
* INPUT:
* devNum - one of three devices
* regNum - 0 or 1
* regVal - value
*
*
* OUTPUT:
* None.
*
* RETURN:
* reg value
*
*******************************************************************************/
MV_STATUS mvBoardTwsiSatRSet(MV_U8 devNum, MV_U8 regNum, MV_U8 regVal)
{
MV_TWSI_SLAVE twsiSlave;
MV_TWSI_ADDR slave;
/* TWSI init */
slave.type = ADDR7_BIT;
slave.address = 0;
mvTwsiInit(0, TWSI_SPEED, mvBoardTclkGet(), &slave, 0);
/* Read MPP module ID */
twsiSlave.slaveAddr.address = mvBoardTwsiAddrGet(BOARD_DEV_TWSI_SATR, devNum);
twsiSlave.slaveAddr.type = mvBoardTwsiAddrTypeGet(BOARD_DEV_TWSI_SATR, devNum);
twsiSlave.validOffset = MV_TRUE;
DB(mvOsPrintf("Board: Write S@R device addr %x, type %x, data %x\n",
twsiSlave.slaveAddr.address, twsiSlave.slaveAddr.type, regVal));
/* Use offset as command */
twsiSlave.offset = regNum;
twsiSlave.moreThen256 = MV_FALSE;
if (MV_OK != mvTwsiWrite(0, &twsiSlave, &regVal, 1)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
DB(mvOsPrintf("Board: Write S@R succeded\n"));
return MV_OK;
}
/*******************************************************************************
* SatR Configuration functions
*******************************************************************************/
MV_U8 mvBoardFreqGet(MV_VOID)
{
MV_U8 sar0, sar1;
sar0 = mvBoardTwsiSatRGet(0, 0);
if (MV_6601_DEV_ID == mvCtrlModelGet()) /* A-MC */
return MSAR6601_CPU_DDR_CLCK_TWSI_EXTRACT(sar0);
sar1 = mvBoardTwsiSatRGet(2, 0);
return MSAR_CPU_DDR_L2_CLCK_TWSI_EXTRACT(sar0, sar1);
}
MV_STATUS mvBoardFreqSet(MV_U8 freqVal)
{
MV_U8 sar0, sar1;
if (MV_6601_DEV_ID == mvCtrlModelGet()){ /* A-MC */
sar0 = mvBoardTwsiSatRGet(0, 0) & ~0x07;
sar0 |= freqVal & 0x7;
if (MV_OK != mvBoardTwsiSatRSet(0, 0, sar0)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
}
else
{
sar0 = freqVal & 0x1f;
if (MV_OK != mvBoardTwsiSatRSet(0, 0, sar0)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
sar1 = mvBoardTwsiSatRGet(2, 0);
sar1 = MV_SET_BIT(sar1, 4, MV_GET_BIT(freqVal, 5));
if (MV_OK != mvBoardTwsiSatRSet(2, 0, sar1)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
}
DB(mvOsPrintf("Board: Write Freq S@R succeeded\n"));
return MV_OK;
}
MV_U8 mvBoardSSCGGet(MV_VOID)
{
MV_U8 sar;
if (MV_6601_DEV_ID == mvCtrlModelGet()){ /* A-MC */
sar = mvBoardTwsiSatRGet(0, 0) & 0x10;
return (sar>>4);
}
sar = mvBoardTwsiSatRGet(1, 0);
return MV_GET_BIT(sar, 2);
}
MV_STATUS mvBoardSSCGSet(MV_U8 val)
{
MV_U8 sar;
if (MV_6601_DEV_ID == mvCtrlModelGet()){ /* A-MC */
sar = mvBoardTwsiSatRGet(0, 0) & ~0x10;
if (val)
sar |=0x10;
if (MV_OK != mvBoardTwsiSatRSet(0, 0, sar)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
}
else {
sar = mvBoardTwsiSatRGet(1, 0);
sar = MV_SET_BIT(sar, 2, (val & 0x1));
if (MV_OK != mvBoardTwsiSatRSet(1, 0, sar)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
}
DB(mvOsPrintf("Board: Write Freq S@R succeeded\n"));
return MV_OK;
}
MV_U8 mvBoardPexClkGet(MV_U8 pexIf)
{
MV_U8 sar;
MV_U8 sarDev;
MV_U8 bit;
if (pexIf == 0) {
sarDev = 2;
bit = 2;
} else {
sarDev = 3;
bit = 0;
}
sar = mvBoardTwsiSatRGet(sarDev, 0);
return MV_GET_BIT(sar, bit);
}
MV_STATUS mvBoardPexClkSet(MV_U8 pexIf, MV_U8 val)
{
MV_U8 sar;
MV_U8 sarDev;
MV_U8 bit;
if (pexIf == 0) {
sarDev = 2;
bit = 2;
} else {
sarDev = 3;
bit = 0;
}
sar = mvBoardTwsiSatRGet(sarDev, 0);
sar = MV_SET_BIT(sar, bit, (val & 0x1));
if (MV_OK != mvBoardTwsiSatRSet(sarDev, 0, sar)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
DB(mvOsPrintf("Board: Write Pex Clock S@R succeeded\n"));
return MV_OK;
}
MV_U8 mvBoardSaRL2ExistGet(MV_VOID)
{
MV_U8 sar;
sar = mvBoardTwsiSatRGet(3, 0);
return MV_GET_BIT(sar, 3);
}
MV_U8 mvBoardSaRL2ExistSet(MV_U8 val)
{
MV_U8 sar;
MV_U8 sarDev;
MV_U8 bit;
sarDev = 3;
bit = 3;
sar = mvBoardTwsiSatRGet(sarDev, 0);
sar = MV_SET_BIT(sar, bit, (val & 0x1));
if (MV_OK != mvBoardTwsiSatRSet(sarDev, 0, sar)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
DB(mvOsPrintf("Board: Write L2-Exist S@R succeeded\n"));
return MV_OK;
}
MV_U8 mvBoardPonGet(MV_VOID)
{
MV_U8 sar;
sar = mvBoardTwsiSatRGet(3, 0);
return MV_GET_BIT(sar, 4);
}
MV_STATUS mvBoardPonSet(MV_U8 val)
{
MV_U8 sar;
sar = mvBoardTwsiSatRGet(3, 0);
sar = MV_SET_BIT(sar, 4, (val & 0x1));
if (MV_OK != mvBoardTwsiSatRSet(3, 0, sar)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
DB(mvOsPrintf("Board: Write Freq S@R succeeded\n"));
return MV_OK;
}
MV_U8 mvBoardTClkGet(MV_VOID)
{
MV_U8 sar;
if (MV_6601_DEV_ID == mvCtrlModelGet()){ /* A-MC */
sar = mvBoardTwsiSatRGet(0, 0);
return ((sar & 0x8))>>3;
}
sar = mvBoardTwsiSatRGet(1, 0);
return (sar & 0x3);
}
MV_STATUS mvBoardTClkSet(MV_U8 val)
{
MV_U8 sar;
if (MV_6601_DEV_ID == mvCtrlModelGet()){ /* A-MC */
sar = mvBoardTwsiSatRGet(0, 0) & ~8;
if (val)
sar |=0x8;
if (MV_OK != mvBoardTwsiSatRSet(0, 0, sar)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
}
else {
sar = mvBoardTwsiSatRGet(1, 0);
sar = ((sar & ~(0x3)) | (val & 0x3));
if (MV_OK != mvBoardTwsiSatRSet(1, 0, sar)) {
DB(mvOsPrintf("Board: Write S@R fail\n"));
return MV_ERROR;
}
}
DB(mvOsPrintf("Board: Write Freq S@R succeeded\n"));
return MV_OK;
}
/*******************************************************************************
* End of SatR Configuration functions
*******************************************************************************/
/*******************************************************************************
* mvBoardEthSataModulesScan
*
* DESCRIPTION:
* Scan the on-board ethernet & Sata complex modules, and return a
* list of all available modules.
*
* INPUT:
* None.
*
* OUTPUT:
* modules - A bitmask of all modules detected on board
* (bitwise or from MV_BOARD_MODULE_ID_CLASS)
*
* RETURN:
* MV_STATUS - MV_OK, MV_ERROR.
*
*******************************************************************************/
MV_STATUS mvBoardEthSataModulesScan(MV_U32 *modules, MV_ETH_COMPLEX_IF_SOURCES *ethSrcCfg)
{
MV_U32 result = 0;
MV_U8 cfg, boardCfg;
MV_STATUS status;
MV_TWSI_SLAVE twsiSlave;
MV_TWSI_ADDR slave;
if (!mvBoardModuleAutoDetectEnabled())
return MV_OK;
/* Go over all possible modules and check for existence */
slave.type = ADDR7_BIT;
slave.address = 0;
mvTwsiInit(0, TWSI_SPEED, mvBoardTclkGet(), &slave, 0);
/* Read the board config EEPROM */
twsiSlave.slaveAddr.address = MV_BOARD_EEPROM_MODULE_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_EEPROM_MODULE_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
status = mvTwsiRead(0, &twsiSlave, &boardCfg, 1);
if (status != MV_OK) {
mvOsPrintf(" mvBoardEthSataModulesScan: Error on mvTwsiRead\n");
*modules = 0;
return status;
}
/* Avanta-MC */
mvOsPrintf(" mvBoardEthSataModulesScan: mvTwsiRead return jumper = 0x%x\n",boardCfg );
if (DB_88F6601_BP_ID == mvBoardIdGet()) {
MV_U8 xcvrValue=4;
if (0 == MV_BOARD_6601_CFG_MAC_SRC(boardCfg))
ethSrcCfg->feGeSrc = EC_MAC0_SRC; /* MAC0 --> GbE PHY, MAC1 --> LP SERDES */
else
ethSrcCfg->feGeSrc = EC_SRC_NONE; /* MAC0 --> LP SERDES, MAC1 --> NONE */
*modules = 0;
/* JP2 LP SerDes connection */
if (MV_BOARD_6601_CFG_LP_SERDES_CON_MASK == MV_BOARD_6601_CFG_LP_SERDES_CON(boardCfg)) {
MV_U32 gppVal = mvGppValueGet(1, MV_GPP0);
if (gppVal == 0){
mvGppValueSet(0, MV_GPP31, 0);
*modules |= MV_BOARD_MODULE_GE_SFP_ID;
}
else {
mvGppValueSet(0, MV_GPP31, MV_GPP31);
mvOsPrintf("mvBoardEthSataModulesScan: Error illegal SFP module configuration\n");
}
} else {
mvGppValueSet(0, MV_GPP31, MV_GPP31);
*modules |= MV_BOARD_MODULE_FE_GE_PHY_ID;
}
/* JP3 LP SerDes mode 2.5G /1.25G */
if (MV_BOARD_6601_CFG_LP_SERDES_MODE_MASK == MV_BOARD_6601_CFG_LP_SERDES_MODE(boardCfg))
ethSrcCfg->macType = EC_SGMII_2_5G;
else
ethSrcCfg->macType = EC_SGMII_1_25G;
/* JP4 FXS presence */
if (0 == MV_BOARD_6601_CFG_FXS(boardCfg))
*modules |= MV_BOARD_MODULE_TDM_1_ID;
/* Configure XCVR mux */
twsiSlave.slaveAddr.address = MV_BOARD_XCVR_MUX_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_XCVR_MUX_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
mvTwsiWrite(0, &twsiSlave, &xcvrValue , 1);
return MV_OK;
}
/* KW2 */
switch (MV_BOARD_CFG_SW_SRC(boardCfg)) {
case 1:
ethSrcCfg->swSrc = EC_MAC1_SRC;
break;
case 2:
ethSrcCfg->swSrc = EC_MAC0_SRC;
break;
case 3:
ethSrcCfg->swSrc = EC_MAC0_MAC1_SRC;
break;
case 0:
default:
ethSrcCfg->swSrc = EC_SRC_NONE;
break;
}
switch (MV_BOARD_CFG_RGMIIA_SRC(boardCfg)) {
case 0:
ethSrcCfg->rgmiiASrc = EC_SW_P6_SRC;
break;
case 1:
ethSrcCfg->rgmiiASrc = EC_MAC0_SRC;
break;
case 2:
ethSrcCfg->rgmiiASrc = EC_MAC1_SRC;
break;
case 3:
ethSrcCfg->rgmiiASrc = EC_SW_P5_SRC;
break;
default:
ethSrcCfg->rgmiiASrc = EC_SRC_NONE;
break;
}
switch (MV_BOARD_CFG_FEGEPHY_SRC(boardCfg)) {
case 1:
ethSrcCfg->feGeSrc = EC_MAC1_SRC;
break;
case 2:
ethSrcCfg->feGeSrc = EC_SW_P0_SRC;
break;
case 3:
ethSrcCfg->feGeSrc = EC_SW_P5_SRC;
break;
case 0:
default:
ethSrcCfg->feGeSrc = EC_SRC_NONE;
break;
}
/* Sata / QSGMII / SGMII */
switch (MV_BOARD_CFG_SERDES_SRC(boardCfg)) {
case 1:
result |= MV_BOARD_MODULE_SATA_ID;
break;
case 2:
result |= MV_BOARD_MODULE_SGMII_ID;
break;
case 3:
result |= MV_BOARD_MODULE_SDIO_ID;
break;
case 0:
default:
break;
}
/* FEGE PHY */
switch (MV_BOARD_CFG_FEGEPHY_SRC(boardCfg)) {
case 1:
case 2:
case 3:
result |= MV_BOARD_MODULE_FE_GE_PHY_ID;
break;
case 0:
default:
break;
}
/* RGMII 0 */
twsiSlave.slaveAddr.address = MV_BOARD_RGMIIA_MODULE_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_RGMIIA_MODULE_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
if (mvBoardTwsiReadByteThruMux(MV_BOARD_RGMIIA_MODULE_MUX_CHNUM, 0, &twsiSlave, &cfg) == MV_OK) {
if (cfg == 0x3)
result |= MV_BOARD_MODULE_RGMIIA_ID;
else if (cfg == 0x6)
result |= MV_BOARD_MODULE_MIIA_ID;
}
/* RGMII 1 */
twsiSlave.slaveAddr.address = MV_BOARD_RGMIIB_MODULE_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_RGMIIB_MODULE_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
if (mvBoardTwsiReadByteThruMux(MV_BOARD_RGMIIB_MODULE_MUX_CHNUM, 0, &twsiSlave, &cfg) == MV_OK) {
if (cfg == 0x3)
result |= MV_BOARD_MODULE_RGMIIB_ID;
else if (cfg == 0x6)
result |= MV_BOARD_MODULE_MIIB_ID;
}
/* QSGMII */
twsiSlave.slaveAddr.address = MV_BOARD_QSGMII_MODULE_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_QSGMII_MODULE_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
if (mvBoardTwsiReadByteThruMux(MV_BOARD_QSGMII_MODULE_MUX_CHNUM, 0, &twsiSlave, &cfg) == MV_OK) {
if (((cfg & 0xf) == 0x8) || ((cfg & 0xf) == 0xb))
result |= MV_BOARD_MODULE_QSGMII_ID;
}
if ((!(result & MV_BOARD_MODULE_QSGMII_ID)) &&
(!((result & MV_BOARD_MODULE_SGMII_ID) && (ethSrcCfg->swSrc == EC_MAC0_SRC))) &&
(!((result & MV_BOARD_MODULE_SGMII_ID) && (ethSrcCfg->swSrc == EC_MAC0_MAC1_SRC))) &&
(ethSrcCfg->swSrc != EC_SRC_NONE))
result |= MV_BOARD_MODULE_4FE_PHY_ID;
/* GE SFP */
twsiSlave.slaveAddr.address = MV_BOARD_GE_SFP_MODULE_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_GE_SFP_MODULE_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
if (mvBoardTwsiReadByteThruMux(MV_BOARD_GE_SFP_MODULE_MUX_CHNUM, 0, &twsiSlave, &cfg) == MV_OK)
result |= MV_BOARD_MODULE_GE_SFP_ID;
*modules = result;
return MV_OK;
}
/*******************************************************************************
* mvBoardIsSdioEnabled
*
* DESCRIPTION:
* Check if SDIO is enabled on KW2-DB board.
* the check is done by reading the on-board EEPROM.
*
* INPUT:
* None.
*
* OUTPUT:
* None.
*
* RETURN:
* MV_TRUE if SDIO is enabled,
* MV_FALSE otherwise.
* On all boards except DB this function will return MV_TRUE.
*
*******************************************************************************/
MV_STATUS mvBoardIsSdioEnabled(MV_VOID)
{
MV_U8 boardCfg;
MV_TWSI_SLAVE twsiSlave;
MV_TWSI_ADDR slave;
if (MV_6601_DEV_ID == mvCtrlModelGet()) /* no sdio on A-MC */
return MV_FALSE;
if (!mvBoardModuleAutoDetectEnabled())
return MV_TRUE;
/* Go over all possible modules and check for existence */
slave.type = ADDR7_BIT;
slave.address = 0;
mvTwsiInit(0, TWSI_SPEED, mvBoardTclkGet(), &slave, 0);
/* Read the board config EEPROM */
twsiSlave.slaveAddr.address = MV_BOARD_EEPROM_MODULE_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_EEPROM_MODULE_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
if (mvTwsiRead(0, &twsiSlave, &boardCfg, 1) != MV_OK)
return MV_FALSE;
if (MV_BOARD_CFG_SERDES_SRC(boardCfg) == 3)
return MV_TRUE;
return MV_FALSE;
}
/*******************************************************************************
* mvBoardTdmModulesScan
*
* DESCRIPTION:
* Scan the on-board TDM modules.
*
* INPUT:
* None.
*
* OUTPUT:
* modules - A bitmask of all modules detected on board
* (bitwise or from MV_BOARD_MODULE_ID_CLASS)
*
* RETURN:
* MV_STATUS - MV_OK, MV_ERROR.
*
*******************************************************************************/
MV_STATUS mvBoardTdmModulesScan(MV_VOID)
{
MV_U32 result = 0;
MV_U8 cfg;
MV_TWSI_SLAVE twsiSlave;
MV_U32 boardId = mvBoardIdGet();
/* Perform scan only for DB board. */
if (!mvBoardModuleAutoDetectEnabled()) {
/* We have only a single Slic config for RD boards. */
BOARD_INFO(boardId)->boardTdmInfoIndex = 0;
return MV_OK;
}
if (mvBoardStaticModuleConfig == MV_TRUE) {
BOARD_INFO(boardId)->boardTdmInfoIndex = MV_BRD_MODULE_CFG_TDM_GET(mvBoardModuleConfig);
result = 1;
}
if (MV_6601_DEV_ID == mvCtrlModelGet()) /* detect the TDM in A-MC in mvBoardMppIdUpdate */
return MV_OK;
/* TDM-3215 */
if (result == 0) {
twsiSlave.slaveAddr.address = MV_BOARD_TDM_3215_MODULE_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_TDM_MODULE_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
if (mvBoardTwsiReadByteThruMux(MV_BOARD_TDM_MODULE_MUX_CHNUM, 0, &twsiSlave, &cfg) == MV_OK) {
BOARD_INFO(boardId)->boardTdmInfoIndex = BOARD_TDM_SLIC_3215;
result = 1;
}
}
/* TDM-880 */
if (result == 0) {
twsiSlave.slaveAddr.address = MV_BOARD_TDM_880_MODULE_ADDR;
twsiSlave.slaveAddr.type = MV_BOARD_TDM_MODULE_ADDR_TYPE;
twsiSlave.validOffset = MV_TRUE;
twsiSlave.offset = 0;
twsiSlave.moreThen256 = MV_FALSE;
if (mvBoardTwsiReadByteThruMux(MV_BOARD_TDM_MODULE_MUX_CHNUM, 0, &twsiSlave, &cfg) == MV_OK) {
BOARD_INFO(boardId)->boardTdmInfoIndex = BOARD_TDM_SLIC_880;
result = 1;
}
}