/* * Copyright 2007,2009 Free Software Foundation, Inc. * Copyright 2009 Ettus Research LLC * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #ifdef HAVE_CONFIG_H #include #endif #include "../x300/x300_defs.h" #include "ethernet.h" #include "cron.h" #include #include "wb_i2c.h" #include "wb_utils.h" //#include "memory_map.h" //#include "eth_phy.h" //#include "pic.h" //#include "hal_io.h" //#include "nonstdio.h" #include #include #include "xge_phy.h" #include "xge_mac.h" #include #define VERBOSE 0 #define NETHS 2 // # of ethernet interfaces static bool links_up[NETHS] = {}; //////////////////////////////////////////////////////////////////////// // // 10 Gig Ethernet MAC. // typedef struct { volatile uint32_t config; // WO volatile uint32_t int_pending; // Clear-on-read volatile uint32_t int_status; // RO volatile uint32_t int_mask; // RW volatile uint32_t mdio_data; volatile uint32_t mdio_addr; volatile uint32_t mdio_op; volatile uint32_t mdio_control; volatile uint32_t gpio; } xge_regs_t; #define xge_regs ((xge_regs_t *) base) #define SFPP_STATUS_MODABS_CHG (1 << 5) // Has MODABS changed since last read? #define SFPP_STATUS_TXFAULT_CHG (1 << 4) // Has TXFAULT changed since last read? #define SFPP_STATUS_RXLOS_CHG (1 << 3) // Has RXLOS changed since last read? #define SFPP_STATUS_MODABS (1 << 2) // MODABS state #define SFPP_STATUS_TXFAULT (1 << 1) // TXFAULT state #define SFPP_STATUS_RXLOS (1 << 0) // RXLOS state int ethernet_ninterfaces(void) { return NETHS; } //////////////////////////////////////////////////////////////////////// // // Clause 45 MDIO used for 10Gig Ethernet has two bus transactions to complete a transfer. // An initial transaction sets up the address, and a subsequent one transfers the read or write data. // static uint32_t xge_read_mdio(const uint32_t base, const uint32_t address, const uint32_t device, const uint32_t port) { // Set register address each iteration xge_regs->mdio_addr = address; // Its a clause 45 device. We want to ADDRESS xge_regs->mdio_op = XGE_MDIO_CLAUSE(CLAUSE45) | XGE_MDIO_OP(MDIO_ADDRESS) | XGE_MDIO_ADDR(port) | XGE_MDIO_MMD(device); // Start MDIO bus transaction xge_regs->mdio_control = 1; // Wait until bus transaction complete while (xge_regs->mdio_control == 1); // Its a clause 45 device. We want to READ xge_regs->mdio_op = XGE_MDIO_CLAUSE(CLAUSE45) | XGE_MDIO_OP(MDIO_READ) | XGE_MDIO_ADDR(port) | XGE_MDIO_MMD(device); // Start MDIO bus transaction xge_regs->mdio_control = 1; // Wait until bus transaction complete while (xge_regs->mdio_control == 1); // Read MDIO data return(xge_regs->mdio_data); } static void xge_write_mdio(const uint32_t base, const uint32_t address, const uint32_t device, const uint32_t port, const uint32_t data) { // Set register address each iteration xge_regs->mdio_addr = address; // Its a clause 45 device. We want to ADDRESS xge_regs->mdio_op = XGE_MDIO_CLAUSE(CLAUSE45) | XGE_MDIO_OP(MDIO_ADDRESS) | XGE_MDIO_ADDR(port) | XGE_MDIO_MMD(device); // Start MDIO bus transaction xge_regs->mdio_control = 1; // Wait until bus transaction complete while (xge_regs->mdio_control == 1); // Write new value to mdio_write_data reg. xge_regs->mdio_data = data; // Its a clause 45 device. We want to WRITE xge_regs->mdio_op = XGE_MDIO_CLAUSE(CLAUSE45) | XGE_MDIO_OP(MDIO_WRITE) | XGE_MDIO_ADDR(port) | XGE_MDIO_MMD(device); // Start MDIO bus transaction xge_regs->mdio_control = 1; // Wait until bus transaction complete while (xge_regs->mdio_control == 1); } //////////////////////////////////////////////////////////////////////// // // Clause 22 MDIO used for 1Gig Ethernet has one bus transaction to complete a transfer. // static uint32_t ge_read_mdio(const uint32_t base, const uint32_t address, const uint32_t port) { // Its a clause 22 device. We want to READ xge_regs->mdio_op = XGE_MDIO_CLAUSE(CLAUSE22) | XGE_MDIO_OP(MDIO_C22_READ) | XGE_MDIO_ADDR(port) | address; // Start MDIO bus transaction xge_regs->mdio_control = 1; // Wait until bus transaction complete while (xge_regs->mdio_control == 1); // Read MDIO data return(xge_regs->mdio_data); } static void ge_write_mdio(const uint32_t base, const uint32_t address, const uint32_t port, const uint32_t data) { // Write new value to mdio_write_data reg. xge_regs->mdio_data = data; // Its a clause 22 device. We want to WRITE xge_regs->mdio_op = XGE_MDIO_CLAUSE(CLAUSE22) | XGE_MDIO_OP(MDIO_C22_WRITE) | XGE_MDIO_ADDR(port) | address; // Start MDIO bus transaction xge_regs->mdio_control = 1; // Wait until bus transaction complete while (xge_regs->mdio_control == 1); } //////////////////////////////////////////////////////////////////////// // // Read and write MDIO independent of type // static uint32_t read_mdio(const uint8_t eth, const uint32_t address, const uint32_t device, const uint32_t port) { const uint32_t rb_addr = (eth==0) ? RB_ETH_TYPE0 : RB_ETH_TYPE1; const uint32_t base = (eth==0) ? XGE0_BASE : XGE1_BASE; if (wb_peek32(SR_ADDR(RB0_BASE, rb_addr)) != 0) { return xge_read_mdio(base, address, device, port); } else { return ge_read_mdio(base, address, port); } } static void write_mdio(const uint8_t eth, const uint32_t address, const uint32_t device, const uint32_t port, const uint32_t data) { const uint32_t rb_addr = (eth==0) ? RB_ETH_TYPE0 : RB_ETH_TYPE1; const uint32_t base = (eth==0) ? XGE0_BASE : XGE1_BASE; if (wb_peek32(SR_ADDR(RB0_BASE, rb_addr)) != 0) { return xge_write_mdio(base, address, device, port, data); } else { return ge_write_mdio(base, address, port, data); } } //////////////////////////////////////////////////////////////////////// // // Read an 8-bit word from a device attached to the PHY's i2c bus. // static int xge_i2c_rd(const uint32_t base, const uint8_t i2c_dev_addr, const uint8_t i2c_word_addr) { uint8_t buf; // IJB. CHECK HERE FOR MODET. Bail immediately if no module // SFF-8472 defines a hardcoded bus address of 0xA0, an 8bit internal address and a register map. // Write the random access address to the SPF module if (wb_i2c_write(base, i2c_dev_addr, &i2c_word_addr, 1) == false) return(-1); // Now read back a byte of data if (wb_i2c_read(base, i2c_dev_addr, &buf, 1) == false) return(-1); return((int) buf); } //////////////////////////////////////////////////////////////////////// // // Read identity of SFP+ module for XGE PHY // // (base is i2c controller) static int xge_read_sfpp_type(const uint32_t base, const uint32_t delay_ms) { int x; // Delay read of SFPP if (delay_ms) sleep_ms(delay_ms); // Read ID code from SFP x = xge_i2c_rd(base, MODULE_DEV_ADDR, 3); // I2C Error? if (x < 0) { UHD_FW_TRACE(ERROR, "I2C error in SFPP_TYPE."); return x; } // Decode module type. These registers and values are defined in SFF-8472 if (x & 0x01) // Active 1X Infinband Copper { goto twinax; } if (x & 0x10) { UHD_FW_TRACE(DEBUG, "SFFP_TYPE_SR."); return SFFP_TYPE_SR; } if (x & 0x20) { UHD_FW_TRACE(DEBUG, "SFFP_TYPE_LR."); return SFFP_TYPE_LR; } if (x & 0x40) { UHD_FW_TRACE(DEBUG, "SFFP_TYPE_LRM."); return SFFP_TYPE_LRM; } // Search for legacy 1000-Base SFP types x = xge_i2c_rd(base, MODULE_DEV_ADDR, 0x6); if (x < 0) { UHD_FW_TRACE(ERROR, "I2C error in SFPP_TYPE."); return x; } if (x & 0x01) { UHD_FW_TRACE(DEBUG, "SFFP_TYPE_1000BASE_SX."); return SFFP_TYPE_1000BASE_SX; } if (x & 0x02) { UHD_FW_TRACE(DEBUG, "SFFP_TYPE_1000BASE_LX."); return SFFP_TYPE_1000BASE_LX; } if (x & 0x08) { UHD_FW_TRACE(DEBUG, "SFFP_TYPE_1000BASE_T."); return SFFP_TYPE_1000BASE_T; } // Not one of the standard optical types..now try to deduce if it's twinax aka 10GSFP+CU // which is not covered explicitly in SFF-8472 x = xge_i2c_rd(base, MODULE_DEV_ADDR, 8); if (x < 0) { UHD_FW_TRACE(ERROR, "I2C error in SFPP_TYPE."); return x; } if ((x & 4) == 0) // Passive SFP+ cable type goto unknown; // x = xge_i2c_rd(MODULE_DEV_ADDR, 6); // UHD_FW_TRACE(DEBUG, "SFP+ reg6 read as %x",x); // if (x < 0) // return x; // if (x != 0x04) // Returns 1000Base-CX as Compliance code // goto unknown; x = xge_i2c_rd(base, MODULE_DEV_ADDR, 0xA); if (x < 0) { UHD_FW_TRACE(ERROR, "I2C error in SFPP_TYPE."); return x; } if (x & 0x80) { twinax: // Reports 1200 MBytes/sec fibre channel speed..close enough to 10G ethernet! x = xge_i2c_rd(base, MODULE_DEV_ADDR, 0x12); if (x < 0) { UHD_FW_TRACE(ERROR, "I2C error in SFPP_TYPE."); return x; } UHD_FW_TRACE(DEBUG, "TwinAx."); // If cable length support is greater than 10M then pick correct type return x > 10 ? SFFP_TYPE_TWINAX_LONG : SFFP_TYPE_TWINAX; } unknown: UHD_FW_TRACE(WARN, "Unknown SFP+ type."); // Not a supported Module type return SFFP_TYPE_UNKNOWN; } static void xge_mac_init(const uint32_t base) { UHD_FW_TRACE(DEBUG, "Begining XGE MAC init sequence."); xge_regs->config = XGE_TX_ENABLE; } // base is pointer to XGE MAC on Wishbone. static void xge_phy_init(const uint8_t eth, const uint32_t mdio_port) { int x; // Read LASI Ctrl register to capture state. //y = xge_read_mdio(0x9002,XGE_MDIO_DEVICE_PMA,XGE_MDIO_ADDR_PHY_A); UHD_FW_TRACE(DEBUG, "Begining XGE PHY init sequence."); // Software reset x = read_mdio(eth, 0x0, XGE_MDIO_DEVICE_PMA,mdio_port); x = x | (1 << 15); write_mdio(eth, 0x0,XGE_MDIO_DEVICE_PMA,mdio_port,x); uint32_t loopCount = 0; while(x&(1<<15)) { x = read_mdio(eth, 0x0,XGE_MDIO_DEVICE_PMA,mdio_port); if( loopCount++ > 200 ) break; // usually succeeds after 22 or 23 polls } } void update_eth_state(const uint32_t eth) { const bool old_link_up = links_up[eth]; const uint32_t status_reg_addr = (eth==0) ? RB_SFPP_STATUS0 : RB_SFPP_STATUS1; const bool is_10g = (wb_peek32(SR_ADDR(RB0_BASE, eth == 0 ? RB_ETH_TYPE0 : RB_ETH_TYPE1)) == 1); uint32_t sfpp_status = wb_peek32(SR_ADDR(RB0_BASE, status_reg_addr)) & 0xFFFF; if ((sfpp_status & (SFPP_STATUS_RXLOS|SFPP_STATUS_TXFAULT|SFPP_STATUS_MODABS)) == 0) { //SFP+ pin state changed. Reinitialize PHY and MAC if (is_10g) { xge_mac_init((eth==0) ? XGE0_BASE : XGE1_BASE); xge_phy_init(eth ,MDIO_PORT); } else { //No-op for 1G } int8_t timeout = 100; bool link_up = false; do { if (is_10g) { link_up = ((read_mdio(eth, XGE_MDIO_STATUS1,XGE_MDIO_DEVICE_PMA,MDIO_PORT)) & (1 << 2)) != 0; } else { link_up = ((wb_peek32(SR_ADDR(RB0_BASE, status_reg_addr)) >> 16) & 0x1) != 0; } } while (!link_up && timeout-- > 0); links_up[eth] = link_up; } else { links_up[eth] = false; } if (!old_link_up && links_up[eth]) u3_net_stack_send_arp_request(eth, u3_net_stack_get_ip_addr(eth)); UHD_FW_TRACE_FSTR(INFO, "The link on eth port %u is %s", eth, links_up[eth]?"up":"down"); } void poll_sfpp_status(const uint32_t eth) { uint32_t x; // Has MODDET/MODAbS changed since we last looked? x = wb_peek32(SR_ADDR(RB0_BASE, (eth==0) ? RB_SFPP_STATUS0 : RB_SFPP_STATUS1 )); if (x & SFPP_STATUS_RXLOS_CHG) UHD_FW_TRACE_FSTR(DEBUG, "eth%1d RXLOS changed state: %d", eth, (x & SFPP_STATUS_RXLOS)); if (x & SFPP_STATUS_TXFAULT_CHG) UHD_FW_TRACE_FSTR(DEBUG, "eth%1d TXFAULT changed state: %d", eth, ((x & SFPP_STATUS_TXFAULT) >> 1)); if (x & SFPP_STATUS_MODABS_CHG) UHD_FW_TRACE_FSTR(DEBUG, "eth%1d MODABS changed state: %d", eth, ((x & SFPP_STATUS_MODABS) >> 2)); //update the link up status if ((x & SFPP_STATUS_RXLOS_CHG) || (x & SFPP_STATUS_TXFAULT_CHG) || (x & SFPP_STATUS_MODABS_CHG)) { update_eth_state(eth); } if (x & SFPP_STATUS_MODABS_CHG) { // MODDET has changed state since last checked if (x & SFPP_STATUS_MODABS) { // MODDET is high, module currently removed. UHD_FW_TRACE_FSTR(INFO, "An SFP+ module has been removed from eth port %d.", eth); } else { // MODDET is low, module currently inserted. // Return status. UHD_FW_TRACE_FSTR(INFO, "A new SFP+ module has been inserted into eth port %d.", eth); xge_read_sfpp_type((eth==0) ? I2C0_BASE : I2C2_BASE,1); } } } void ethernet_init(const uint32_t eth) { #ifdef UHD_FW_TRACE_LEVEL uint32_t x = wb_peek32(SR_ADDR(RB0_BASE, (eth==0) ? RB_SFPP_STATUS0 : RB_SFPP_STATUS1 )); UHD_FW_TRACE_FSTR(DEBUG, "eth%1d SFP initial state: RXLOS: %d TXFAULT: %d MODABS: %d", eth, (x & SFPP_STATUS_RXLOS), ((x & SFPP_STATUS_TXFAULT) >> 1), ((x & SFPP_STATUS_MODABS) >> 2)); #endif links_up[eth] = false; update_eth_state(eth); } // // Debug code to verbosely read XGE MDIO registers below here. // void decode_reg(uint32_t address, uint32_t device, uint32_t data) { UHD_FW_TRACE_FSTR(DEBUG, "[MDIO Register Dump for Addr=%x, Device=%x]\n- Raw Value = %x", address, device, data); int x; switch(address) { case XGE_MDIO_CONTROL1: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "CONTROL1: %x = ", data); for (x=15; x >= 0 ; x--) if ((data & (1 << x)) != 0) // Bits set. switch(x) { case 15: UHD_FW_TRACE_SHORT(DEBUG, "Reset,"); break; case 14: UHD_FW_TRACE_SHORT(DEBUG, "Loopback,"); break; case 11: UHD_FW_TRACE_SHORT(DEBUG, "Low Power Mode,"); break; case 5:case 4:case 3:case 2: UHD_FW_TRACE_SHORT(DEBUG, "RESERVED speed value,"); break; case 0: UHD_FW_TRACE_SHORT(DEBUG, "PMA loopback,"); break; } //else // Bits clear. //switch (x) { //case 13: case 6: UHD_FW_TRACE_SHORT(DEBUG, " None 10Gb/s speed set!"); break; //} UHD_FW_TRACE_SHORT(DEBUG, " \n"); break; case XGE_MDIO_STATUS1: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "STATUS1: %x = ", data); for (x=15; x >= 0 ; x--) if ((data & (1 << x)) != 0) // Bits set. switch(x) { case 7: UHD_FW_TRACE_SHORT(DEBUG, "Fault Detected,"); break; case 2: UHD_FW_TRACE_SHORT(DEBUG, "Link is Up,"); break; case 1: UHD_FW_TRACE_SHORT(DEBUG, "Supports Low Power,"); break; } else // Bits Clear switch(x) { case 2: UHD_FW_TRACE_SHORT(DEBUG, "Link is Down,"); break; } UHD_FW_TRACE_SHORT(DEBUG, " \n"); break; case XGE_MDIO_SPEED: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "SPEED ABILITY: %x = ", data); for (x=15; x >= 0 ; x--) if ((data & (1 << x)) != 0) // Bits set. switch(x) { case 15:case 14:case 13:case 12:case 11:case 10:case 9: case 8:case 7:case 6:case 5:case 4:case 3:case 2:case 1: UHD_FW_TRACE_SHORT(DEBUG, "RESERVED bits set!,"); break; case 0: UHD_FW_TRACE_SHORT(DEBUG, "Capable of 10Gb/s,"); } else // Bits clear. switch(x) { case 0: UHD_FW_TRACE_SHORT(DEBUG, "Incapable of 10Gb/s,"); break; } UHD_FW_TRACE_SHORT(DEBUG, " \n"); break; case XGE_MDIO_DEVICES1: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "DEVICES IN PACKAGE: %x = ", data); for (x=15; x >= 0 ; x--) if ((data & (1 << x)) != 0) // Bits set. switch(x) { case 7: UHD_FW_TRACE_SHORT(DEBUG, "Auto-Negotiation,"); break; case 6: UHD_FW_TRACE_SHORT(DEBUG, "TC,"); break; case 5: UHD_FW_TRACE_SHORT(DEBUG, "DTE XS,"); break; case 4: UHD_FW_TRACE_SHORT(DEBUG, "PHY XS,"); break; case 3: UHD_FW_TRACE_SHORT(DEBUG, "PCS,"); break; case 2: UHD_FW_TRACE_SHORT(DEBUG, "WIS,"); break; case 1: UHD_FW_TRACE_SHORT(DEBUG, "PMD/PMA,"); break; case 0: UHD_FW_TRACE_SHORT(DEBUG, "Clause 22 registers,"); break; } UHD_FW_TRACE_SHORT(DEBUG, " \n"); break; case XGE_MDIO_DEVICES2: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "DEVICES IN PACKAGE (cont): %x = ", data); for (x=15; x >= 0 ; x--) if ((data & (1 << x)) != 0) // Bits set. switch(x) { case 15: UHD_FW_TRACE_SHORT(DEBUG, "Vendor device 2,"); break; case 14: UHD_FW_TRACE_SHORT(DEBUG, "Vendor device 1,"); break; case 13: UHD_FW_TRACE_SHORT(DEBUG, "Clause 22 extension,"); break; } UHD_FW_TRACE_SHORT(DEBUG, " \n"); break; case XGE_MDIO_CONTROL2: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "CONTROL2: %x = ", data); // PMA/PMD if (device == XGE_MDIO_DEVICE_PMA) switch((data & 0xf)) { case 0xF: UHD_FW_TRACE_SHORT(DEBUG, "10BASE-T,"); break; case 0xE: UHD_FW_TRACE_SHORT(DEBUG, "100BASE-TX,"); break; case 0xD: UHD_FW_TRACE_SHORT(DEBUG, "1000BASE-KX,"); break; case 0xC: UHD_FW_TRACE_SHORT(DEBUG, "1000BASE-T,"); break; case 0xB: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-KR,"); break; case 0xA: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-KX4,"); break; case 0x9: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-T,"); break; case 0x8: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-LRM,"); break; case 0x7: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-SR,"); break; case 0x6: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-LR,"); break; case 0x5: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-ER,"); break; case 0x4: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-LX4,"); break; // case 0x3: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-SW,"); break; // case 0x2: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-LW,"); break; // case 0x1: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-EW,"); break; case 0x0: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-CX4,"); break; } else if (device == XGE_MDIO_DEVICE_PCS) // PCS switch((data & 0x3)) { case 0x3: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-T PCS,"); break; case 0x2: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-W PCS,"); break; case 0x1: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-X PCS,"); break; case 0x0: UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-R PCS,"); break; } UHD_FW_TRACE_SHORT(DEBUG, " \n"); break; case XGE_MDIO_STATUS2: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "STATUS2: %x = ", data); for (x=15; x >= 0 ; x--) if ((data & (1 << x)) != 0) // Bits set. switch(x) { case 15: if ((data & (1 << 14)) == 0) UHD_FW_TRACE_SHORT(DEBUG, "Device responding,"); break; case 13: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "Able detect a Tx fault,"); break; case 12: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "Able detect an Rx fault,"); break; case 11: UHD_FW_TRACE_SHORT(DEBUG, "Fault on Tx path,"); break; case 10: UHD_FW_TRACE_SHORT(DEBUG, "Fault on Rx path,"); break; case 9: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "Extended abilities in Reg1.11,"); break; case 8: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "Able to disable TX,"); break; case 7: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-SR,"); break; case 6: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-LR,"); break; case 5: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-ER,"); break; case 4: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-LX4,"); break; case 3: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-SW,"); break; case 2: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-LW,"); break; case 1: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "10GBASE-EW,"); break; case 0: if (device == XGE_MDIO_DEVICE_PMA) UHD_FW_TRACE_SHORT(DEBUG, "loopback,"); break; } UHD_FW_TRACE_SHORT(DEBUG, " \n"); break; case XGE_MDIO_LANESTATUS: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "LANE STATUS: %x = ", data); for (x=15; x >= 0 ; x--) if ((data & (1 << x)) != 0) // Bits set. switch(x) { case 12: UHD_FW_TRACE_SHORT(DEBUG, "Lanes aligned,"); break; case 11: UHD_FW_TRACE_SHORT(DEBUG, "Able to generate test patterns,"); break; case 3: UHD_FW_TRACE_SHORT(DEBUG, "Lane 3 synced,"); break; case 2: UHD_FW_TRACE_SHORT(DEBUG, "Lane 2 synced,"); break; case 1: UHD_FW_TRACE_SHORT(DEBUG, "Lane 1 synced,"); break; case 0: UHD_FW_TRACE_SHORT(DEBUG, "Lane 0 synced,"); break; } else // Bits clear switch(x) { case 3: UHD_FW_TRACE_SHORT(DEBUG, "Lane 3 not synced,"); break; case 2: UHD_FW_TRACE_SHORT(DEBUG, "Lane 2 not synced,"); break; case 1: UHD_FW_TRACE_SHORT(DEBUG, "Lane 1 not synced,"); break; case 0: UHD_FW_TRACE_SHORT(DEBUG, "Lane 0 not synced,"); break; } UHD_FW_TRACE_SHORT(DEBUG, " \n"); break; case XILINX_CORE_VERSION: UHD_FW_TRACE_FSTR_SHORT(DEBUG, "XILINX CORE VERSION: %x ",data); UHD_FW_TRACE_FSTR_SHORT(DEBUG, "Version: %d.%d ",((data&0xf000)>>12),((data&0xf00)>>8)); UHD_FW_TRACE_FSTR_SHORT(DEBUG, "Patch: %d ",((data&0xE)>>1)); UHD_FW_TRACE_SHORT(DEBUG, " \n"); if (data&0x1) UHD_FW_TRACE(WARN, "Evaluation Version of core"); break; default: UHD_FW_TRACE_SHORT(DEBUG, "Register @ address: "); UHD_FW_TRACE_FSTR_SHORT(DEBUG, "%x",address); UHD_FW_TRACE_SHORT(DEBUG, " has value: "); UHD_FW_TRACE_FSTR_SHORT(DEBUG, "%x\n",data); break; } } void dump_mdio_regs(const uint8_t eth, uint32_t mdio_port) { volatile unsigned int x; int y; unsigned int regs_a[9] = {0,1,4,5,6,7,8,32,33}; unsigned int regs_b[10] = {0,1,4,5,6,7,8,10,11,65535}; for (y = 0; y < 10; y++) { // Read MDIO data x = read_mdio(eth,regs_b[y],XGE_MDIO_DEVICE_PMA,mdio_port); decode_reg(regs_b[y],XGE_MDIO_DEVICE_PMA,x); } for (y = 0; y < 9; y++) { // Read MDIO data x = read_mdio(eth,regs_a[y],XGE_MDIO_DEVICE_PCS,mdio_port); decode_reg(regs_a[y],XGE_MDIO_DEVICE_PCS,x); } /* for (y = 0; y < 8; y++) */ /* { */ /* // Read MDIO data */ /* x = xge_read_mdio(base,regs_a[y],XGE_MDIO_DEVICE_PHY_XS,mdio_port); */ /* decode_reg(regs_a[y],XGE_MDIO_DEVICE_PHY_XS,x); */ /* } */ /* for (y = 0; y < 8; y++) */ /* { */ /* // Read MDIO data */ /* x = xge_read_mdio(base,regs_a[y],XGE_MDIO_DEVICE_DTE_XS,mdio_port); */ /* decode_reg(regs_a[y],XGE_MDIO_DEVICE_DTE_XS,x); */ /* } */ } bool ethernet_get_link_up(const uint32_t eth) { return links_up[eth]; }