/* * Copyright (c) 2015, Freescale Semiconductor, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * o Redistributions of source code must retain the above copyright notice, this list * of conditions and the following disclaimer. * * o 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. * * o Neither the name of Freescale Semiconductor, Inc. nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * 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 HOLDER 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. */ #include "fsl_phy.h" /******************************************************************************* * Definitions ******************************************************************************/ /*! @brief Defines the timeout macro. */ #define PHY_TIMEOUT_COUNT 0xFFFFFU /******************************************************************************* * Prototypes ******************************************************************************/ /*! * @brief Get the ENET instance from peripheral base address. * * @param base ENET peripheral base address. * @return ENET instance. */ extern uint32_t ENET_GetInstance(ENET_Type *base); /******************************************************************************* * Variables ******************************************************************************/ /*! @brief Pointers to enet clocks for each instance. */ extern clock_ip_name_t s_enetClock[FSL_FEATURE_SOC_ENET_COUNT]; /******************************************************************************* * Code ******************************************************************************/ status_t PHY_Init(ENET_Type *base, uint32_t phyAddr, uint32_t srcClock_Hz) { uint32_t bssReg; uint32_t counter = PHY_TIMEOUT_COUNT; status_t result = kStatus_Success; uint32_t instance = ENET_GetInstance(base); /* Set SMI first. */ CLOCK_EnableClock(s_enetClock[instance]); ENET_SetSMI(base, srcClock_Hz, false); /* Reset PHY. */ result = PHY_Write(base, phyAddr, PHY_BASICCONTROL_REG, PHY_BCTL_RESET_MASK); if (result == kStatus_Success) { /* Set the negotiation. */ result = PHY_Write(base, phyAddr, PHY_AUTONEG_ADVERTISE_REG, (PHY_100BASETX_FULLDUPLEX_MASK | PHY_100BASETX_HALFDUPLEX_MASK | PHY_10BASETX_FULLDUPLEX_MASK | PHY_10BASETX_HALFDUPLEX_MASK | 0x1U)); if (result == kStatus_Success) { result = PHY_Write(base, phyAddr, PHY_BASICCONTROL_REG, (PHY_BCTL_AUTONEG_MASK | PHY_BCTL_RESTART_AUTONEG_MASK)); if (result == kStatus_Success) { /* Check auto negotiation complete. */ while (counter --) { result = PHY_Read(base, phyAddr, PHY_BASICSTATUS_REG, &bssReg); if ( result == kStatus_Success) { if ((bssReg & PHY_BSTATUS_AUTONEGCOMP_MASK) != 0) { break; } } if (!counter) { return kStatus_PHY_AutoNegotiateFail; } } } } } return result; } status_t PHY_Write(ENET_Type *base, uint32_t phyAddr, uint32_t phyReg, uint32_t data) { uint32_t counter; /* Clear the SMI interrupt event. */ ENET_ClearInterruptStatus(base, ENET_EIR_MII_MASK); /* Starts a SMI write command. */ ENET_StartSMIWrite(base, phyAddr, phyReg, kENET_MiiWriteValidFrame, data); /* Wait for SMI complete. */ for (counter = PHY_TIMEOUT_COUNT; counter > 0; counter--) { if (ENET_GetInterruptStatus(base) & ENET_EIR_MII_MASK) { break; } } /* Check for timeout. */ if (!counter) { return kStatus_PHY_SMIVisitTimeout; } /* Clear MII interrupt event. */ ENET_ClearInterruptStatus(base, ENET_EIR_MII_MASK); return kStatus_Success; } status_t PHY_Read(ENET_Type *base, uint32_t phyAddr, uint32_t phyReg, uint32_t *dataPtr) { assert(dataPtr); uint32_t counter; /* Clear the MII interrupt event. */ ENET_ClearInterruptStatus(base, ENET_EIR_MII_MASK); /* Starts a SMI read command operation. */ ENET_StartSMIRead(base, phyAddr, phyReg, kENET_MiiReadValidFrame); /* Wait for MII complete. */ for (counter = PHY_TIMEOUT_COUNT; counter > 0; counter--) { if (ENET_GetInterruptStatus(base) & ENET_EIR_MII_MASK) { break; } } /* Check for timeout. */ if (!counter) { return kStatus_PHY_SMIVisitTimeout; } /* Get data from MII register. */ *dataPtr = ENET_ReadSMIData(base); /* Clear MII interrupt event. */ ENET_ClearInterruptStatus(base, ENET_EIR_MII_MASK); return kStatus_Success; } status_t PHY_EnableLoopback(ENET_Type *base, uint32_t phyAddr, phy_loop_t mode, bool enable) { status_t result; uint32_t data = 0; /* Set the loop mode. */ if (enable) { if (mode == kPHY_LocalLoop) { /* First read the current status in control register. */ result = PHY_Read(base, phyAddr, PHY_BASICCONTROL_REG, &data); if (result == kStatus_Success) { return PHY_Write(base, phyAddr, PHY_BASICCONTROL_REG, (data | PHY_BCTL_LOOP_MASK)); } } else { /* First read the current status in control register. */ result = PHY_Read(base, phyAddr, PHY_CONTROL2_REG, &data); if (result == kStatus_Success) { return PHY_Write(base, phyAddr, PHY_CONTROL2_REG, (data | PHY_CTL2_REMOTELOOP_MASK)); } } } else { /* Disable the loop mode. */ if (mode == kPHY_LocalLoop) { /* First read the current status in the basic control register. */ result = PHY_Read(base, phyAddr, PHY_BASICCONTROL_REG, &data); if (result == kStatus_Success) { return PHY_Write(base, phyAddr, PHY_BASICCONTROL_REG, (data & ~PHY_BCTL_LOOP_MASK)); } } else { /* First read the current status in control one register. */ result = PHY_Read(base, phyAddr, PHY_CONTROL2_REG, &data); if (result == kStatus_Success) { return PHY_Write(base, phyAddr, PHY_CONTROL2_REG, (data & ~PHY_CTL2_REMOTELOOP_MASK)); } } } return result; } status_t PHY_GetLinkStatus(ENET_Type *base, uint32_t phyAddr, bool *status) { assert(status); status_t result = kStatus_Success; uint32_t data; /* Read the basic status register. */ result = PHY_Read(base, phyAddr, PHY_BASICSTATUS_REG, &data); if (result == kStatus_Success) { if (!(PHY_BSTATUS_LINKSTATUS_MASK & data)) { /* link down. */ *status = false; } else { /* link up. */ *status = true; } } return result; } status_t PHY_GetLinkSpeedDuplex(ENET_Type *base, uint32_t phyAddr, phy_speed_t *speed, phy_duplex_t *duplex) { assert(duplex); status_t result = kStatus_Success; uint32_t data, ctlReg; /* Read the control two register. */ result = PHY_Read(base, phyAddr, PHY_CONTROL1_REG, &ctlReg); if (result == kStatus_Success) { data = ctlReg & PHY_CTL1_SPEEDUPLX_MASK; if ((PHY_CTL1_10FULLDUPLEX_MASK == data) || (PHY_CTL1_100FULLDUPLEX_MASK == data)) { /* Full duplex. */ *duplex = kPHY_FullDuplex; } else { /* Half duplex. */ *duplex = kPHY_HalfDuplex; } data = ctlReg & PHY_CTL1_SPEEDUPLX_MASK; if ((PHY_CTL1_100HALFDUPLEX_MASK == data) || (PHY_CTL1_100FULLDUPLEX_MASK == data)) { /* 100M speed. */ *speed = kPHY_Speed100M; } else { /* 10M speed. */ *speed = kPHY_Speed10M; } } return result; }