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gfiber / uboot / mindspeed / 60c2f14fab77ed869f08f4a146127e2e7129e2cf / . / cpu / ixp / npe / IxEthMii.c
blob: 4d92f17eef779a9943aaea344f451f6d3b6a44ee [file] [log] [blame]
/**
* @file IxEthMii.c
*
* @author Intel Corporation
* @date
*
* @brief MII control functions
*
* Design Notes:
*
*
* @par
* IXP400 SW Release version 2.0
*
* -- Copyright Notice --
*
* @par
* Copyright 2001-2005, Intel Corporation.
* All rights reserved.
*
* @par
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the Intel Corporation nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* @par
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ``AS IS''
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* @par
* -- End of Copyright Notice --
*/
#include "IxOsal.h"
#include "IxEthAcc.h"
#include "IxEthMii_p.h"
#ifdef __wince
#include "IxOsPrintf.h"
#endif
/* Array to store the phy IDs of the discovered phys */
PRIVATE UINT32 ixEthMiiPhyId[IXP425_ETH_ACC_MII_MAX_ADDR];
/*********************************************************
*
* Scan for PHYs on the MII bus. This function returns
* an array of booleans, one for each PHY address.
* If a PHY is found at a particular address, the
* corresponding entry in the array is set to TRUE.
*
*/
PUBLIC IX_STATUS
ixEthMiiPhyScan(BOOL phyPresent[], UINT32 maxPhyCount)
{
UINT32 i;
UINT16 regval, regvalId1, regvalId2;
/*Search for PHYs on the MII*/
/*Search for existant phys on the MDIO bus*/
if ((phyPresent == NULL) ||
(maxPhyCount > IXP425_ETH_ACC_MII_MAX_ADDR))
{
return IX_FAIL;
}
/* fill the array */
for(i=0;
i<IXP425_ETH_ACC_MII_MAX_ADDR;
i++)
{
phyPresent[i] = FALSE;
}
/* iterate through the PHY addresses */
for(i=0;
maxPhyCount > 0 && i<IXP425_ETH_ACC_MII_MAX_ADDR;
i++)
{
ixEthMiiPhyId[i] = IX_ETH_MII_INVALID_PHY_ID;
if(ixEthAccMiiReadRtn(i,
IX_ETH_MII_CTRL_REG,
&regval) == IX_ETH_ACC_SUCCESS)
{
if((regval & 0xffff) != 0xffff)
{
maxPhyCount--;
/*Need to read the register twice here to flush PHY*/
ixEthAccMiiReadRtn(i, IX_ETH_MII_PHY_ID1_REG, &regvalId1);
ixEthAccMiiReadRtn(i, IX_ETH_MII_PHY_ID1_REG, &regvalId1);
ixEthAccMiiReadRtn(i, IX_ETH_MII_PHY_ID2_REG, &regvalId2);
ixEthMiiPhyId[i] = (regvalId1 << IX_ETH_MII_REG_SHL) | regvalId2;
if ((ixEthMiiPhyId[i] == IX_ETH_MII_KS8995_PHY_ID)
|| (ixEthMiiPhyId[i] == IX_ETH_MII_LXT971_PHY_ID)
|| (ixEthMiiPhyId[i] == IX_ETH_MII_LXT972_PHY_ID)
|| (ixEthMiiPhyId[i] == IX_ETH_MII_LXT973_PHY_ID)
|| (ixEthMiiPhyId[i] == IX_ETH_MII_LXT973A3_PHY_ID)
|| (ixEthMiiPhyId[i] == IX_ETH_MII_LXT9785_PHY_ID)
)
{
/* supported phy */
phyPresent[i] = TRUE;
} /* end of if(ixEthMiiPhyId) */
else
{
if (ixEthMiiPhyId[i] != IX_ETH_MII_INVALID_PHY_ID)
{
/* unsupported phy */
ixOsalLog (IX_OSAL_LOG_LVL_ERROR,
IX_OSAL_LOG_DEV_STDOUT,
"ixEthMiiPhyScan : unexpected Mii PHY ID %8.8x\n",
ixEthMiiPhyId[i], 2, 3, 4, 5, 6);
ixEthMiiPhyId[i] = IX_ETH_MII_UNKNOWN_PHY_ID;
phyPresent[i] = TRUE;
}
}
}
}
}
return IX_SUCCESS;
}
/************************************************************
*
* Configure the PHY at the specified address
*
*/
PUBLIC IX_STATUS
ixEthMiiPhyConfig(UINT32 phyAddr,
BOOL speed100,
BOOL fullDuplex,
BOOL autonegotiate)
{
UINT16 regval=0;
/* parameter check */
if ((phyAddr < IXP425_ETH_ACC_MII_MAX_ADDR) &&
(ixEthMiiPhyId[phyAddr] != IX_ETH_MII_INVALID_PHY_ID))
{
/*
* set the control register
*/
if(autonegotiate)
{
regval |= IX_ETH_MII_CR_AUTO_EN | IX_ETH_MII_CR_RESTART;
}
else
{
if(speed100)
{
regval |= IX_ETH_MII_CR_100;
}
if(fullDuplex)
{
regval |= IX_ETH_MII_CR_FDX;
}
} /* end of if-else() */
if (ixEthAccMiiWriteRtn(phyAddr,
IX_ETH_MII_CTRL_REG,
regval) == IX_ETH_ACC_SUCCESS)
{
return IX_SUCCESS;
}
} /* end of if(phyAddr) */
return IX_FAIL;
}
/******************************************************************
*
* Enable the PHY Loopback at the specified address
*/
PUBLIC IX_STATUS
ixEthMiiPhyLoopbackEnable (UINT32 phyAddr)
{
UINT16 regval ;
if ((phyAddr < IXP425_ETH_ACC_MII_MAX_ADDR) &&
(IX_ETH_MII_INVALID_PHY_ID != ixEthMiiPhyId[phyAddr]))
{
/* read/write the control register */
if(ixEthAccMiiReadRtn (phyAddr,
IX_ETH_MII_CTRL_REG,
&regval)
== IX_ETH_ACC_SUCCESS)
{
if(ixEthAccMiiWriteRtn (phyAddr,
IX_ETH_MII_CTRL_REG,
regval | IX_ETH_MII_CR_LOOPBACK)
== IX_ETH_ACC_SUCCESS)
{
return IX_SUCCESS;
}
}
}
return IX_FAIL;
}
/******************************************************************
*
* Disable the PHY Loopback at the specified address
*/
PUBLIC IX_STATUS
ixEthMiiPhyLoopbackDisable (UINT32 phyAddr)
{
UINT16 regval ;
if ((phyAddr < IXP425_ETH_ACC_MII_MAX_ADDR) &&
(IX_ETH_MII_INVALID_PHY_ID != ixEthMiiPhyId[phyAddr]))
{
/* read/write the control register */
if(ixEthAccMiiReadRtn (phyAddr,
IX_ETH_MII_CTRL_REG,
&regval)
== IX_ETH_ACC_SUCCESS)
{
if(ixEthAccMiiWriteRtn (phyAddr,
IX_ETH_MII_CTRL_REG,
regval & (~IX_ETH_MII_CR_LOOPBACK))
== IX_ETH_ACC_SUCCESS)
{
return IX_SUCCESS;
}
}
}
return IX_FAIL;
}
/******************************************************************
*
* Reset the PHY at the specified address
*/
PUBLIC IX_STATUS
ixEthMiiPhyReset(UINT32 phyAddr)
{
UINT32 timeout;
UINT16 regval;
if ((phyAddr < IXP425_ETH_ACC_MII_MAX_ADDR) &&
(ixEthMiiPhyId[phyAddr] != IX_ETH_MII_INVALID_PHY_ID))
{
if ((ixEthMiiPhyId[phyAddr] == IX_ETH_MII_LXT971_PHY_ID) ||
(ixEthMiiPhyId[phyAddr] == IX_ETH_MII_LXT972_PHY_ID) ||
(ixEthMiiPhyId[phyAddr] == IX_ETH_MII_LXT973_PHY_ID) ||
(ixEthMiiPhyId[phyAddr] == IX_ETH_MII_LXT973A3_PHY_ID) ||
(ixEthMiiPhyId[phyAddr] == IX_ETH_MII_LXT9785_PHY_ID)
)
{
/* use the control register to reset the phy */
ixEthAccMiiWriteRtn(phyAddr,
IX_ETH_MII_CTRL_REG,
IX_ETH_MII_CR_RESET);
/* poll until the reset bit is cleared */
timeout = 0;
do
{
ixOsalSleep (IX_ETH_MII_RESET_POLL_MS);
/* read the control register and check for timeout */
ixEthAccMiiReadRtn(phyAddr,
IX_ETH_MII_CTRL_REG,
&regval);
if ((regval & IX_ETH_MII_CR_RESET) == 0)
{
/* timeout bit is self-cleared */
break;
}
timeout += IX_ETH_MII_RESET_POLL_MS;
}
while (timeout < IX_ETH_MII_RESET_DELAY_MS);
/* check for timeout */
if (timeout >= IX_ETH_MII_RESET_DELAY_MS)
{
ixEthAccMiiWriteRtn(phyAddr, IX_ETH_MII_CTRL_REG,
IX_ETH_MII_CR_NORM_EN);
return IX_FAIL;
}
return IX_SUCCESS;
} /* end of if(ixEthMiiPhyId) */
else if (ixEthMiiPhyId[phyAddr] == IX_ETH_MII_KS8995_PHY_ID)
{
/* reset bit is reserved, just reset the control register */
ixEthAccMiiWriteRtn(phyAddr, IX_ETH_MII_CTRL_REG,
IX_ETH_MII_CR_NORM_EN);
return IX_SUCCESS;
}
else
{
/* unknown PHY, set the control register reset bit,
* wait 2 s. and clear the control register.
*/
ixEthAccMiiWriteRtn(phyAddr, IX_ETH_MII_CTRL_REG,
IX_ETH_MII_CR_RESET);
ixOsalSleep (IX_ETH_MII_RESET_DELAY_MS);
ixEthAccMiiWriteRtn(phyAddr, IX_ETH_MII_CTRL_REG,
IX_ETH_MII_CR_NORM_EN);
return IX_SUCCESS;
} /* end of if-else(ixEthMiiPhyId) */
} /* end of if(phyAddr) */
return IX_FAIL;
}
/*****************************************************************
*
* Link state query functions
*/
PUBLIC IX_STATUS
ixEthMiiLinkStatus(UINT32 phyAddr,
BOOL *linkUp,
BOOL *speed100,
BOOL *fullDuplex,
BOOL *autoneg)
{
UINT16 ctrlRegval, statRegval, regval, regval4, regval5;
/* check the parameters */
if ((linkUp == NULL) ||
(speed100 == NULL) ||
(fullDuplex == NULL) ||
(autoneg == NULL))
{
return IX_FAIL;
}
*linkUp = FALSE;
*speed100 = FALSE;
*fullDuplex = FALSE;
*autoneg = FALSE;
if ((phyAddr < IXP425_ETH_ACC_MII_MAX_ADDR) &&
(ixEthMiiPhyId[phyAddr] != IX_ETH_MII_INVALID_PHY_ID))
{
if ((ixEthMiiPhyId[phyAddr] == IX_ETH_MII_LXT971_PHY_ID) ||
(ixEthMiiPhyId[phyAddr] == IX_ETH_MII_LXT972_PHY_ID) ||
(ixEthMiiPhyId[phyAddr] == IX_ETH_MII_LXT9785_PHY_ID)
)
{
/* --------------------------------------------------*/
/* Retrieve information from PHY specific register */
/* --------------------------------------------------*/
if (ixEthAccMiiReadRtn(phyAddr,
IX_ETH_MII_STAT2_REG,
&regval) != IX_ETH_ACC_SUCCESS)
{
return IX_FAIL;
}
*linkUp = ((regval & IX_ETH_MII_SR2_LINK) != 0);
*speed100 = ((regval & IX_ETH_MII_SR2_100) != 0);
*fullDuplex = ((regval & IX_ETH_MII_SR2_FD) != 0);
*autoneg = ((regval & IX_ETH_MII_SR2_AUTO) != 0);
return IX_SUCCESS;
} /* end of if(ixEthMiiPhyId) */
else
{
/* ----------------------------------------------------*/
/* Retrieve information from status and ctrl registers */
/* ----------------------------------------------------*/
if (ixEthAccMiiReadRtn(phyAddr,
IX_ETH_MII_CTRL_REG,
&ctrlRegval) != IX_ETH_ACC_SUCCESS)
{
return IX_FAIL;
}
ixEthAccMiiReadRtn(phyAddr, IX_ETH_MII_STAT_REG, &statRegval);
*linkUp = ((statRegval & IX_ETH_MII_SR_LINK_STATUS) != 0);
if (*linkUp)
{
*autoneg = ((ctrlRegval & IX_ETH_MII_CR_AUTO_EN) != 0) &&
((statRegval & IX_ETH_MII_SR_AUTO_SEL) != 0) &&
((statRegval & IX_ETH_MII_SR_AUTO_NEG) != 0);
if (*autoneg)
{
/* mask the current stat values with the capabilities */
ixEthAccMiiReadRtn(phyAddr, IX_ETH_MII_AN_ADS_REG, &regval4);
ixEthAccMiiReadRtn(phyAddr, IX_ETH_MII_AN_PRTN_REG, &regval5);
/* merge the flags from the 3 registers */
regval = (statRegval & ((regval4 & regval5) << 6));
/* initialise from status register values */
if ((regval & IX_ETH_MII_SR_TX_FULL_DPX) != 0)
{
/* 100 Base X full dplx */
*speed100 = TRUE;
*fullDuplex = TRUE;
return IX_SUCCESS;
}
if ((regval & IX_ETH_MII_SR_TX_HALF_DPX) != 0)
{
/* 100 Base X half dplx */
*speed100 = TRUE;
return IX_SUCCESS;
}
if ((regval & IX_ETH_MII_SR_10T_FULL_DPX) != 0)
{
/* 10 mb full dplx */
*fullDuplex = TRUE;
return IX_SUCCESS;
}
if ((regval & IX_ETH_MII_SR_10T_HALF_DPX) != 0)
{
/* 10 mb half dplx */
return IX_SUCCESS;
}
} /* end of if(autoneg) */
else
{
/* autonegotiate not complete, return setup parameters */
*speed100 = ((ctrlRegval & IX_ETH_MII_CR_100) != 0);
*fullDuplex = ((ctrlRegval & IX_ETH_MII_CR_FDX) != 0);
}
} /* end of if(linkUp) */
} /* end of if-else(ixEthMiiPhyId) */
} /* end of if(phyAddr) */
else
{
return IX_FAIL;
} /* end of if-else(phyAddr) */
return IX_SUCCESS;
}
/*****************************************************************
*
* Link state display functions
*/
PUBLIC IX_STATUS
ixEthMiiPhyShow (UINT32 phyAddr)
{
BOOL linkUp, speed100, fullDuplex, autoneg;
UINT16 cregval;
UINT16 sregval;
ixEthAccMiiReadRtn(phyAddr, IX_ETH_MII_STAT_REG, &sregval);
ixEthAccMiiReadRtn(phyAddr, IX_ETH_MII_CTRL_REG, &cregval);
/* get link information */
if (ixEthMiiLinkStatus(phyAddr,
&linkUp,
&speed100,
&fullDuplex,
&autoneg) != IX_ETH_ACC_SUCCESS)
{
printf("PHY Status unknown\n");
return IX_FAIL;
}
printf("PHY ID [phyAddr]: %8.8x\n",ixEthMiiPhyId[phyAddr]);
printf( " Status reg: %4.4x\n",sregval);
printf( " control reg: %4.4x\n",cregval);
/* display link information */
printf("PHY Status:\n");
printf(" Link is %s\n",
(linkUp ? "Up" : "Down"));
if((sregval & IX_ETH_MII_SR_REMOTE_FAULT) != 0)
{
printf(" Remote fault detected\n");
}
printf(" Auto Negotiation %s\n",
(autoneg ? "Completed" : "Not Completed"));
printf("PHY Configuration:\n");
printf(" Speed %sMb/s\n",
(speed100 ? "100" : "10"));
printf(" %s Duplex\n",
(fullDuplex ? "Full" : "Half"));
printf(" Auto Negotiation %s\n",
(autoneg ? "Enabled" : "Disabled"));
return IX_SUCCESS;
}