/*-----------------------------------------------------------------------------+ | | This source code has been made available to you by IBM on an AS-IS | basis. Anyone receiving this source is licensed under IBM | copyrights to use it in any way he or she deems fit, including | copying it, modifying it, compiling it, and redistributing it either | with or without modifications. No license under IBM patents or | patent applications is to be implied by the copyright license. | | Any user of this software should understand that IBM cannot provide | technical support for this software and will not be responsible for | any consequences resulting from the use of this software. | | Any person who transfers this source code or any derivative work | must include the IBM copyright notice, this paragraph, and the | preceding two paragraphs in the transferred software. | | COPYRIGHT I B M CORPORATION 1995 | LICENSED MATERIAL - PROGRAM PROPERTY OF I B M +-----------------------------------------------------------------------------*/ /*-----------------------------------------------------------------------------+ | | File Name: miiphy.c | | Function: This module has utilities for accessing the MII PHY through | the EMAC3 macro. | | Author: Mark Wisner | +-----------------------------------------------------------------------------*/ /* define DEBUG for debugging output (obviously ;-)) */ #if 0 #define DEBUG #endif #include #include #include #include #include #include #include <405_mal.h> #include #if !defined(CONFIG_PHY_CLK_FREQ) #define CONFIG_PHY_CLK_FREQ 0 #endif /***********************************************************/ /* Dump out to the screen PHY regs */ /***********************************************************/ void miiphy_dump (char *devname, unsigned char addr) { unsigned long i; unsigned short data; for (i = 0; i < 0x1A; i++) { if (miiphy_read (devname, addr, i, &data)) { printf ("read error for reg %lx\n", i); return; } printf ("Phy reg %lx ==> %4x\n", i, data); /* jump to the next set of regs */ if (i == 0x07) i = 0x0f; } /* end for loop */ } /* end dump */ /***********************************************************/ /* (Re)start autonegotiation */ /***********************************************************/ int phy_setup_aneg (char *devname, unsigned char addr) { u16 bmcr; #if defined(CONFIG_PHY_DYNAMIC_ANEG) /* * Set up advertisement based on capablilities reported by the PHY. * This should work for both copper and fiber. */ u16 bmsr; #if defined(CONFIG_PHY_GIGE) u16 exsr = 0x0000; #endif miiphy_read (devname, addr, PHY_BMSR, &bmsr); #if defined(CONFIG_PHY_GIGE) if (bmsr & PHY_BMSR_EXT_STAT) miiphy_read (devname, addr, PHY_EXSR, &exsr); if (exsr & (PHY_EXSR_1000XF | PHY_EXSR_1000XH)) { /* 1000BASE-X */ u16 anar = 0x0000; if (exsr & PHY_EXSR_1000XF) anar |= PHY_X_ANLPAR_FD; if (exsr & PHY_EXSR_1000XH) anar |= PHY_X_ANLPAR_HD; miiphy_write (devname, addr, PHY_ANAR, anar); } else #endif { u16 anar, btcr; miiphy_read (devname, addr, PHY_ANAR, &anar); anar &= ~(0x5000 | PHY_ANLPAR_T4 | PHY_ANLPAR_TXFD | PHY_ANLPAR_TX | PHY_ANLPAR_10FD | PHY_ANLPAR_10); miiphy_read (devname, addr, PHY_1000BTCR, &btcr); btcr &= ~(0x00FF | PHY_1000BTCR_1000FD | PHY_1000BTCR_1000HD); if (bmsr & PHY_BMSR_100T4) anar |= PHY_ANLPAR_T4; if (bmsr & PHY_BMSR_100TXF) anar |= PHY_ANLPAR_TXFD; if (bmsr & PHY_BMSR_100TXH) anar |= PHY_ANLPAR_TX; if (bmsr & PHY_BMSR_10TF) anar |= PHY_ANLPAR_10FD; if (bmsr & PHY_BMSR_10TH) anar |= PHY_ANLPAR_10; miiphy_write (devname, addr, PHY_ANAR, anar); #if defined(CONFIG_PHY_GIGE) if (exsr & PHY_EXSR_1000TF) btcr |= PHY_1000BTCR_1000FD; if (exsr & PHY_EXSR_1000TH) btcr |= PHY_1000BTCR_1000HD; miiphy_write (devname, addr, PHY_1000BTCR, btcr); #endif } #else /* defined(CONFIG_PHY_DYNAMIC_ANEG) */ /* * Set up standard advertisement */ u16 adv; miiphy_read (devname, addr, PHY_ANAR, &adv); adv |= (PHY_ANLPAR_ACK | PHY_ANLPAR_TXFD | PHY_ANLPAR_TX | PHY_ANLPAR_10FD | PHY_ANLPAR_10); miiphy_write (devname, addr, PHY_ANAR, adv); miiphy_read (devname, addr, PHY_1000BTCR, &adv); adv |= (0x0300); miiphy_write (devname, addr, PHY_1000BTCR, adv); #endif /* defined(CONFIG_PHY_DYNAMIC_ANEG) */ /* Start/Restart aneg */ miiphy_read (devname, addr, PHY_BMCR, &bmcr); bmcr |= (PHY_BMCR_AUTON | PHY_BMCR_RST_NEG); miiphy_write (devname, addr, PHY_BMCR, bmcr); return 0; } /***********************************************************/ /* read a phy reg and return the value with a rc */ /***********************************************************/ /* AMCC_TODO: * Find out of the choice for the emac for MDIO is from the bridges, * i.e. ZMII or RGMII as approporiate. If the bridges are not used * to determine the emac for MDIO, then is the SDR0_ETH_CFG[MDIO_SEL] * used? If so, then this routine below does not apply to the 460EX/GT. * * sr: Currently on 460EX only EMAC0 works with MDIO, so we always * return EMAC0 offset here * vg: For 460EX/460GT if internal GPCS PHY address is specified * return appropriate EMAC offset */ unsigned int miiphy_getemac_offset(u8 addr) { #if (defined(CONFIG_440) && \ !defined(CONFIG_440SP) && !defined(CONFIG_440SPE) && \ !defined(CONFIG_460EX) && !defined(CONFIG_460GT)) && \ defined(CONFIG_NET_MULTI) unsigned long zmii; unsigned long eoffset; /* Need to find out which mdi port we're using */ zmii = in_be32((void *)ZMII_FER); if (zmii & (ZMII_FER_MDI << ZMII_FER_V (0))) /* using port 0 */ eoffset = 0; else if (zmii & (ZMII_FER_MDI << ZMII_FER_V (1))) /* using port 1 */ eoffset = 0x100; else if (zmii & (ZMII_FER_MDI << ZMII_FER_V (2))) /* using port 2 */ eoffset = 0x400; else if (zmii & (ZMII_FER_MDI << ZMII_FER_V (3))) /* using port 3 */ eoffset = 0x600; else { /* None of the mdi ports are enabled! */ /* enable port 0 */ zmii |= ZMII_FER_MDI << ZMII_FER_V (0); out_be32((void *)ZMII_FER, zmii); eoffset = 0; /* need to soft reset port 0 */ zmii = in_be32((void *)EMAC_M0); zmii |= EMAC_M0_SRST; out_be32((void *)EMAC_M0, zmii); } return (eoffset); #else #if defined(CONFIG_NET_MULTI) && defined(CONFIG_405EX) unsigned long rgmii; int devnum = 1; rgmii = in_be32((void *)RGMII_FER); if (rgmii & (1 << (19 - devnum))) return 0x100; #endif #if defined(CONFIG_460EX) || defined(CONFIG_460GT) u32 mode_reg; u32 eoffset = 0; switch (addr) { #if defined(CONFIG_HAS_ETH1) && defined(CONFIG_GPCS_PHY1_ADDR) case CONFIG_GPCS_PHY1_ADDR: mode_reg = in_be32((void *)EMAC_M1 + 0x100); if (addr == EMAC_M1_IPPA_GET(mode_reg)) eoffset = 0x100; break; #endif #if defined(CONFIG_HAS_ETH2) && defined(CONFIG_GPCS_PHY2_ADDR) case CONFIG_GPCS_PHY2_ADDR: mode_reg = in_be32((void *)EMAC_M1 + 0x300); if (addr == EMAC_M1_IPPA_GET(mode_reg)) eoffset = 0x300; break; #endif #if defined(CONFIG_HAS_ETH3) && defined(CONFIG_GPCS_PHY3_ADDR) case CONFIG_GPCS_PHY3_ADDR: mode_reg = in_be32((void *)EMAC_M1 + 0x400); if (addr == EMAC_M1_IPPA_GET(mode_reg)) eoffset = 0x400; break; #endif default: eoffset = 0; break; } return eoffset; #endif return 0; #endif } static int emac_miiphy_wait(u32 emac_reg) { u32 sta_reg; int i; /* wait for completion */ i = 0; do { sta_reg = in_be32((void *)EMAC_STACR + emac_reg); if (i++ > 5) { debug("%s [%d]: Timeout! EMAC_STACR=0x%0x\n", __func__, __LINE__, sta_reg); return -1; } udelay(10); } while ((sta_reg & EMAC_STACR_OC) == EMAC_STACR_OC_MASK); return 0; } static int emac_miiphy_command(u8 addr, u8 reg, int cmd, u16 value) { u32 emac_reg; u32 sta_reg; emac_reg = miiphy_getemac_offset(addr); /* wait for completion */ if (emac_miiphy_wait(emac_reg) != 0) return -1; sta_reg = reg; /* reg address */ /* set clock (50Mhz) and read flags */ #if defined(CONFIG_440GX) || defined(CONFIG_440SPE) || \ defined(CONFIG_440EPX) || defined(CONFIG_440GRX) || \ defined(CONFIG_460EX) || defined(CONFIG_460GT) || \ defined(CONFIG_405EX) #if defined(CONFIG_IBM_EMAC4_V4) /* EMAC4 V4 changed bit setting */ sta_reg = (sta_reg & ~EMAC_STACR_OP_MASK) | cmd; #else sta_reg |= cmd; #endif #else sta_reg = (sta_reg | cmd) & ~EMAC_STACR_CLK_100MHZ; #endif /* Some boards (mainly 405EP based) define the PHY clock freqency fixed */ sta_reg = sta_reg | CONFIG_PHY_CLK_FREQ; sta_reg = sta_reg | ((u32)addr << 5); /* Phy address */ sta_reg = sta_reg | EMAC_STACR_OC_MASK; /* new IBM emac v4 */ if (cmd == EMAC_STACR_WRITE) memcpy(&sta_reg, &value, 2); /* put in data */ out_be32((void *)EMAC_STACR + emac_reg, sta_reg); debug("%s [%d]: sta_reg=%08x\n", __func__, __LINE__, sta_reg); /* wait for completion */ if (emac_miiphy_wait(emac_reg) != 0) return -1; debug("%s [%d]: sta_reg=%08x\n", __func__, __LINE__, sta_reg); if ((sta_reg & EMAC_STACR_PHYE) != 0) return -1; return 0; } int emac4xx_miiphy_read (char *devname, unsigned char addr, unsigned char reg, unsigned short *value) { unsigned long sta_reg; unsigned long emac_reg; emac_reg = miiphy_getemac_offset(addr); if (emac_miiphy_command(addr, reg, EMAC_STACR_READ, 0) != 0) return -1; sta_reg = in_be32((void *)EMAC_STACR + emac_reg); *value = *(u16 *)(&sta_reg); return 0; } /***********************************************************/ /* write a phy reg and return the value with a rc */ /***********************************************************/ int emac4xx_miiphy_write (char *devname, unsigned char addr, unsigned char reg, unsigned short value) { return emac_miiphy_command(addr, reg, EMAC_STACR_WRITE, value); }