/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #define LINK_MONITOR_PERIOD (1000 * 1000) #define LM_WAIT_MULTIPLIER 8 #define SERDES_RDY_WT_INTERVAL 50 #define MAX_SERDES_RDY_RETRIES 10 #define TN1010_SPEED_1G 1 #define TN1010_SPEED_10G 0 #define TN1010_AN_IN_PROG 0 /* Auto negotiation in progress */ #define TN1010_AN_COMPLETE 1 #define TN1010_AN_RSVD 2 #define TN1010_AN_FAILED 3 extern uint32_t nxge_no_link_notify; extern boolean_t nxge_no_msg; extern uint32_t nxge_lb_dbg; extern boolean_t nxge_jumbo_enable; extern uint32_t nxge_jumbo_mtu; /* The following functions may be found in nxge_main.c */ extern void nxge_mmac_kstat_update(p_nxge_t nxgep, mac_addr_slot_t slot, boolean_t factory); extern int nxge_m_mmac_add(void *arg, mac_multi_addr_t *maddr); extern int nxge_m_mmac_remove(void *arg, mac_addr_slot_t slot); typedef enum { CHECK_LINK_RESCHEDULE, CHECK_LINK_STOP } check_link_state_t; static check_link_state_t nxge_check_link_stop(nxge_t *); /* * Ethernet broadcast address definition. */ static ether_addr_st etherbroadcastaddr = {{0xff, 0xff, 0xff, 0xff, 0xff, 0xff}}; /* * Ethernet zero address definition. */ static ether_addr_st etherzeroaddr = {{0x0, 0x0, 0x0, 0x0, 0x0, 0x0}}; /* * Supported chip types */ static uint32_t nxge_supported_cl45_ids[] = { BCM8704_DEV_ID, MARVELL_88X_201X_DEV_ID, BCM8706_DEV_ID, TN1010_DEV_ID }; static uint32_t nxge_supported_cl22_ids[] = { BCM5464R_PHY_ID, BCM5482_PHY_ID }; #define NUM_CLAUSE_45_IDS (sizeof (nxge_supported_cl45_ids) / \ sizeof (uint32_t)) #define NUM_CLAUSE_22_IDS (sizeof (nxge_supported_cl22_ids) / \ sizeof (uint32_t)) /* * static functions */ static uint32_t nxge_get_cl45_pma_pmd_id(p_nxge_t, int); static uint32_t nxge_get_cl45_pcs_id(p_nxge_t, int); static uint32_t nxge_get_cl22_phy_id(p_nxge_t, int); static boolean_t nxge_is_supported_phy(uint32_t, uint8_t); static boolean_t nxge_is_phy_present(p_nxge_t, int, uint32_t, uint32_t); static nxge_status_t nxge_n2_serdes_init(p_nxge_t); static nxge_status_t nxge_neptune_10G_serdes_init(p_nxge_t); static nxge_status_t nxge_1G_serdes_init(p_nxge_t); static nxge_status_t nxge_10G_link_intr_stop(p_nxge_t); static nxge_status_t nxge_10G_link_intr_start(p_nxge_t); static nxge_status_t nxge_1G_copper_link_intr_stop(p_nxge_t); static nxge_status_t nxge_1G_copper_link_intr_start(p_nxge_t); static nxge_status_t nxge_1G_fiber_link_intr_stop(p_nxge_t); static nxge_status_t nxge_1G_fiber_link_intr_start(p_nxge_t); static nxge_status_t nxge_check_mii_link(p_nxge_t); static nxge_status_t nxge_check_10g_link(p_nxge_t); static nxge_status_t nxge_10G_xcvr_init(p_nxge_t); static nxge_status_t nxge_BCM8704_xcvr_init(p_nxge_t); static nxge_status_t nxge_BCM8706_xcvr_init(p_nxge_t); static nxge_status_t nxge_1G_xcvr_init(p_nxge_t); static void nxge_bcm5464_link_led_off(p_nxge_t); static nxge_status_t nxge_check_mrvl88x2011_link(p_nxge_t, boolean_t *); static nxge_status_t nxge_mrvl88x2011_xcvr_init(p_nxge_t); static nxge_status_t nxge_get_num_of_xaui(uint32_t *port_pma_pmd_dev_id, uint32_t *port_pcs_dev_id, uint32_t *port_phy_id, uint8_t *num_xaui); static nxge_status_t nxge_get_tn1010_speed(p_nxge_t nxgep, uint16_t *speed); static nxge_status_t nxge_set_tn1010_param(p_nxge_t nxgep); static nxge_status_t nxge_tn1010_check(p_nxge_t nxgep, nxge_link_state_t *link_up); static boolean_t nxge_is_tn1010_phy(p_nxge_t nxgep); static nxge_status_t nxge_tn1010_xcvr_init(p_nxge_t nxgep); nxge_status_t nxge_mac_init(p_nxge_t); static nxge_status_t nxge_mii_get_link_mode(p_nxge_t); #ifdef NXGE_DEBUG static void nxge_mii_dump(p_nxge_t); static nxge_status_t nxge_tn1010_reset(p_nxge_t nxgep); static void nxge_dump_tn1010_status_regs(p_nxge_t nxgep); #endif /* * xcvr tables for supported transceivers */ /* * nxge_n2_10G_table is for 10G fiber or serdes on N2-NIU systems. * The Teranetics TN1010 based copper XAUI card can also be used * on N2-NIU systems in 10G mode, but it uses its own table * nxge_n2_10G_tn1010_table below. */ static nxge_xcvr_table_t nxge_n2_10G_table = { nxge_n2_serdes_init, nxge_10G_xcvr_init, nxge_10G_link_intr_stop, nxge_10G_link_intr_start, nxge_check_10g_link, PCS_XCVR }; /* * For the Teranetics TN1010 based copper XAUI card */ static nxge_xcvr_table_t nxge_n2_10G_tn1010_table = { nxge_n2_serdes_init, /* Handle both 1G and 10G */ nxge_tn1010_xcvr_init, /* Handle both 1G and 10G */ nxge_10G_link_intr_stop, nxge_10G_link_intr_start, nxge_check_tn1010_link, /* Will figure out speed */ XPCS_XCVR }; static nxge_xcvr_table_t nxge_n2_1G_table = { nxge_n2_serdes_init, nxge_1G_xcvr_init, nxge_1G_fiber_link_intr_stop, nxge_1G_fiber_link_intr_start, nxge_check_mii_link, PCS_XCVR }; static nxge_xcvr_table_t nxge_n2_1G_tn1010_table = { nxge_n2_serdes_init, nxge_tn1010_xcvr_init, nxge_1G_fiber_link_intr_stop, /* TN1010 is a Cu PHY, but it uses */ nxge_1G_fiber_link_intr_start, /* PCS for 1G, so call fiber func */ nxge_check_tn1010_link, PCS_XCVR }; static nxge_xcvr_table_t nxge_10G_tn1010_table = { nxge_neptune_10G_serdes_init, nxge_tn1010_xcvr_init, nxge_10G_link_intr_stop, nxge_10G_link_intr_start, nxge_check_tn1010_link, XPCS_XCVR }; static nxge_xcvr_table_t nxge_1G_tn1010_table = { nxge_1G_serdes_init, nxge_tn1010_xcvr_init, nxge_1G_fiber_link_intr_stop, nxge_1G_fiber_link_intr_start, nxge_check_tn1010_link, PCS_XCVR }; static nxge_xcvr_table_t nxge_10G_fiber_table = { nxge_neptune_10G_serdes_init, nxge_10G_xcvr_init, nxge_10G_link_intr_stop, nxge_10G_link_intr_start, nxge_check_10g_link, PCS_XCVR }; static nxge_xcvr_table_t nxge_1G_copper_table = { NULL, nxge_1G_xcvr_init, nxge_1G_copper_link_intr_stop, nxge_1G_copper_link_intr_start, nxge_check_mii_link, INT_MII_XCVR }; /* This table is for Neptune portmode == PORT_1G_SERDES cases */ static nxge_xcvr_table_t nxge_1G_fiber_table = { nxge_1G_serdes_init, nxge_1G_xcvr_init, nxge_1G_fiber_link_intr_stop, nxge_1G_fiber_link_intr_start, nxge_check_mii_link, PCS_XCVR }; static nxge_xcvr_table_t nxge_10G_copper_table = { nxge_neptune_10G_serdes_init, NULL, NULL, NULL, NULL, PCS_XCVR }; /* * NXGE_PORT_TN1010 is defined as, * NXGE_PORT_SPD_NONE | (NXGE_PHY_TN1010 << NXGE_PHY_SHIFT) * = 0 | 5 << 16 = 0x50000 * * So NEPTUNE_2_TN1010 = * (NXGE_PORT_TN1010 | * (NXGE_PORT_TN1010 << 4) | * (NXGE_PORT_NONE << 8) | * (NXGE_PORT_NONE << 12)), * = 0x50000 | (0x50000 << 4) * = 0x550000 * * This function partitions nxgep->nxge_hw_p->niu_type (which may have * value NEPTUNE_2_TN1010) and checks if a port has type = NXGE_PORT_TN1010 * = 0x50000 */ static boolean_t nxge_is_tn1010_phy(p_nxge_t nxgep) { uint8_t portn = NXGE_GET_PORT_NUM(nxgep->function_num); if (((nxgep->nxge_hw_p->niu_type >> (NXGE_PORT_TYPE_SHIFT * portn)) & NXGE_PHY_MASK) == NXGE_PORT_TN1010) { return (B_TRUE); } else { return (B_FALSE); } } /* * Figure out nxgep->mac.portmode from nxge.conf, OBP's device properties, * serial EEPROM or VPD if possible. Note that not all systems could get * the portmode information by calling this function. For example, the * Maramba system figures out the portmode information by calling function * nxge_setup_xcvr_table. */ nxge_status_t nxge_get_xcvr_type(p_nxge_t nxgep) { nxge_status_t status = NXGE_OK; char *phy_type; char *prop_val; uint8_t portn = NXGE_GET_PORT_NUM(nxgep->function_num); nxgep->mac.portmode = 0; nxgep->xcvr_addr = 0; /* * First check for hot swappable phy property. */ if (nxgep->hot_swappable_phy == B_TRUE) { nxgep->statsp->mac_stats.xcvr_inuse = HSP_XCVR; nxgep->mac.portmode = PORT_HSP_MODE; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Other: Hot Swappable")); } else if (ddi_prop_exists(DDI_DEV_T_ANY, nxgep->dip, DDI_PROP_DONTPASS | DDI_PROP_NOTPROM, "hot-swappable-phy") == 1) { nxgep->statsp->mac_stats.xcvr_inuse = HSP_XCVR; nxgep->mac.portmode = PORT_HSP_MODE; NXGE_DEBUG_MSG((nxgep, MAC_CTL, ".conf: Hot Swappable")); } else if (nxgep->niu_type == N2_NIU && ddi_prop_exists(DDI_DEV_T_ANY, nxgep->dip, 0, "hot-swappable-phy") == 1) { nxgep->statsp->mac_stats.xcvr_inuse = HSP_XCVR; nxgep->mac.portmode = PORT_HSP_MODE; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "OBP: Hot Swappable")); } /* * MDIO polling support for Monza RTM card, Goa NEM card */ if (nxgep->mac.portmode == PORT_HSP_MODE) { nxgep->hot_swappable_phy = B_TRUE; /* * If this is the 2nd NIU port, then check 2 addresses * to take care of the Goa NEM card. Port 1 can have addr 17 * (in the eval board) or 20 (in the P0 board). */ if (portn == 1) { if (nxge_is_phy_present(nxgep, ALT_GOA_CLAUSE45_PORT1_ADDR, BCM8706_DEV_ID, BCM_PHY_ID_MASK)) { nxgep->xcvr_addr = ALT_GOA_CLAUSE45_PORT1_ADDR; goto found_phy; } } if (nxge_is_phy_present(nxgep, GOA_CLAUSE45_PORT_ADDR_BASE + portn, BCM8706_DEV_ID, BCM_PHY_ID_MASK)) { nxgep->xcvr_addr = GOA_CLAUSE45_PORT_ADDR_BASE + portn; goto found_phy; } nxgep->phy_absent = B_TRUE; goto check_phy_done; found_phy: nxgep->statsp->mac_stats.xcvr_inuse = XPCS_XCVR; nxgep->mac.portmode = PORT_10G_FIBER; nxgep->phy_absent = B_FALSE; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "10G Fiber Xcvr " "found for hot swappable phy")); check_phy_done: return (status); } /* Get phy-type property (May have been set by nxge.conf) */ if ((ddi_prop_lookup_string(DDI_DEV_T_ANY, nxgep->dip, DDI_PROP_DONTPASS | DDI_PROP_NOTPROM, "phy-type", &prop_val)) == DDI_PROP_SUCCESS) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "found conf file: phy-type %s", prop_val)); if (strcmp("xgsd", prop_val) == 0) { nxgep->statsp->mac_stats.xcvr_inuse = XPCS_XCVR; nxgep->mac.portmode = PORT_10G_SERDES; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "found: 10G Serdes")); } else if (strcmp("gsd", prop_val) == 0) { nxgep->statsp->mac_stats.xcvr_inuse = PCS_XCVR; nxgep->mac.portmode = PORT_1G_SERDES; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "1G Serdes")); } else if (strcmp("mif", prop_val) == 0) { nxgep->statsp->mac_stats.xcvr_inuse = INT_MII_XCVR; nxgep->mac.portmode = PORT_1G_COPPER; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "1G Copper Xcvr")); } else if (strcmp("pcs", prop_val) == 0) { nxgep->statsp->mac_stats.xcvr_inuse = PCS_XCVR; nxgep->mac.portmode = PORT_1G_FIBER; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "1G FIBER Xcvr")); } else if (strcmp("xgf", prop_val) == 0) { /* * Before OBP supports new phy-type property * value "xgc", the 10G copper XAUI may carry * "xgf" instead of "xgc". If the OBP is * upgraded to a newer version which supports * "xgc", then the TN1010 related code in this * "xgf" case will not be used anymore. */ if (nxge_is_tn1010_phy(nxgep)) { if ((status = nxge_set_tn1010_param(nxgep)) != NXGE_OK) { return (status); } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "TN1010 Xcvr")); } else { /* For Fiber XAUI */ nxgep->statsp->mac_stats.xcvr_inuse = XPCS_XCVR; nxgep->mac.portmode = PORT_10G_FIBER; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "10G Fiber Xcvr")); } } else if (strcmp("xgc", prop_val) == 0) { if ((status = nxge_set_tn1010_param(nxgep)) != NXGE_OK) return (status); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "TN1010 Xcvr")); } (void) ddi_prop_update_string(DDI_DEV_T_NONE, nxgep->dip, "phy-type", prop_val); ddi_prop_free(prop_val); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_get_xcvr_type: " "Got phy type [0x%x] from conf file", nxgep->mac.portmode)); return (NXGE_OK); } /* Get phy-type property from OBP */ if (nxgep->niu_type == N2_NIU) { if (ddi_prop_lookup_string(DDI_DEV_T_ANY, nxgep->dip, 0, "phy-type", &prop_val) == DDI_PROP_SUCCESS) { if (strcmp("xgf", prop_val) == 0) { /* * Before OBP supports new phy-type property * value "xgc", the 10G copper XAUI may carry * "xgf" instead of "xgc". If the OBP is * upgraded to a newer version which supports * "xgc", then the TN1010 related code in this * "xgf" case will not be used anymore. */ if (nxge_is_tn1010_phy(nxgep)) { if ((status = nxge_set_tn1010_param(nxgep)) != NXGE_OK) { return (status); } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "TN1010 Xcvr")); } else { /* For Fiber XAUI */ nxgep->statsp->mac_stats.xcvr_inuse = XPCS_XCVR; nxgep->mac.portmode = PORT_10G_FIBER; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "10G Fiber Xcvr")); } } else if (strcmp("mif", prop_val) == 0) { nxgep->statsp->mac_stats.xcvr_inuse = INT_MII_XCVR; nxgep->mac.portmode = PORT_1G_COPPER; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "1G Copper Xcvr")); } else if (strcmp("pcs", prop_val) == 0) { nxgep->statsp->mac_stats.xcvr_inuse = PCS_XCVR; nxgep->mac.portmode = PORT_1G_FIBER; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "1G Fiber Xcvr")); } else if (strcmp("xgc", prop_val) == 0) { status = nxge_set_tn1010_param(nxgep); if (status != NXGE_OK) return (status); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "TN1010 Xcvr")); } else if (strcmp("xgsd", prop_val) == 0) { nxgep->statsp->mac_stats.xcvr_inuse = XPCS_XCVR; nxgep->mac.portmode = PORT_10G_SERDES; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "OBP: 10G Serdes")); } else if (strcmp("gsd", prop_val) == 0) { nxgep->statsp->mac_stats.xcvr_inuse = PCS_XCVR; nxgep->mac.portmode = PORT_1G_SERDES; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "OBP: 1G Serdes")); } else { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unknown phy-type: %s", prop_val)); ddi_prop_free(prop_val); return (NXGE_ERROR); } status = NXGE_OK; (void) ddi_prop_update_string(DDI_DEV_T_NONE, nxgep->dip, "phy-type", prop_val); ddi_prop_free(prop_val); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_get_xcvr_type: " "Got phy type [0x%x] from OBP", nxgep->mac.portmode)); return (status); } else { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Exiting...phy-type property not found")); return (NXGE_ERROR); } } if (!nxgep->vpd_info.present) { return (NXGE_OK); } if (!nxgep->vpd_info.ver_valid) { goto read_seeprom; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Reading phy type from expansion ROM")); /* * Try to read the phy type from the vpd data read off the * expansion ROM. */ phy_type = nxgep->vpd_info.phy_type; if (strncmp(phy_type, "mif", 3) == 0) { nxgep->mac.portmode = PORT_1G_COPPER; nxgep->statsp->mac_stats.xcvr_inuse = INT_MII_XCVR; } else if (strncmp(phy_type, "xgf", 3) == 0) { nxgep->mac.portmode = PORT_10G_FIBER; nxgep->statsp->mac_stats.xcvr_inuse = XPCS_XCVR; } else if (strncmp(phy_type, "pcs", 3) == 0) { nxgep->mac.portmode = PORT_1G_FIBER; nxgep->statsp->mac_stats.xcvr_inuse = PCS_XCVR; } else if (strncmp(phy_type, "xgc", 3) == 0) { status = nxge_set_tn1010_param(nxgep); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_get_xcvr_type: Failed to set TN1010 param")); goto read_seeprom; } } else if (strncmp(phy_type, "xgsd", 4) == 0) { nxgep->mac.portmode = PORT_10G_SERDES; nxgep->statsp->mac_stats.xcvr_inuse = XPCS_XCVR; } else if (strncmp(phy_type, "gsd", 3) == 0) { nxgep->mac.portmode = PORT_1G_SERDES; nxgep->statsp->mac_stats.xcvr_inuse = PCS_XCVR; } else { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_get_xcvr_type: Unknown phy type [%c%c%c] in EEPROM", phy_type[0], phy_type[1], phy_type[2])); goto read_seeprom; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_get_xcvr_type: " "Got phy type [0x%x] from VPD", nxgep->mac.portmode)); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_get_xcvr_type")); return (status); read_seeprom: /* * read the phy type from the SEEPROM - NCR registers */ status = nxge_espc_phy_type_get(nxgep); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Failed to get phy type")); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "EEPROM version " "[%s] invalid...please update", nxgep->vpd_info.ver)); } return (status); } /* Set up the PHY specific values. */ nxge_status_t nxge_setup_xcvr_table(p_nxge_t nxgep) { nxge_status_t status = NXGE_OK; uint32_t port_type; uint8_t portn = NXGE_GET_PORT_NUM(nxgep->function_num); uint32_t pcs_id = 0; uint32_t pma_pmd_id = 0; uint32_t phy_id = 0; uint16_t chip_id = 0; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_setup_xcvr_table: port<%d>", portn)); switch (nxgep->niu_type) { case N2_NIU: switch (nxgep->mac.portmode) { case PORT_1G_FIBER: case PORT_1G_SERDES: nxgep->xcvr = nxge_n2_1G_table; nxgep->xcvr_addr = portn; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "NIU 1G %s Xcvr", (nxgep->mac.portmode == PORT_1G_FIBER) ? "Fiber" : "Serdes")); break; case PORT_10G_FIBER: case PORT_10G_SERDES: nxgep->xcvr = nxge_n2_10G_table; if (nxgep->nxge_hw_p->xcvr_addr[portn]) { nxgep->xcvr_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "NIU 10G %s Xcvr", (nxgep->mac.portmode == PORT_10G_FIBER) ? "Fiber" : "Serdes")); break; case PORT_1G_TN1010: nxgep->xcvr = nxge_n2_1G_tn1010_table; nxgep->xcvr_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "TN1010 Copper Xcvr in 1G")); break; case PORT_10G_TN1010: nxgep->xcvr = nxge_n2_10G_tn1010_table; nxgep->xcvr_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "TN1010 Copper Xcvr in 10G")); break; case PORT_HSP_MODE: nxgep->xcvr = nxge_n2_10G_table; nxgep->xcvr.xcvr_inuse = HSP_XCVR; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "NIU 10G Hot " "Swappable Xcvr (not present)")); break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_setup_xcvr_table: " "Unable to determine NIU portmode")); return (NXGE_ERROR); } break; default: if (nxgep->mac.portmode == 0) { /* * Would be the case for platforms like Maramba * in which the phy type could not be got from conf * file, OBP, VPD or Serial PROM. */ if (!NXGE_IS_VALID_NEPTUNE_TYPE(nxgep)) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_setup_xcvr_table:" " Invalid Neptune type [0x%x]", nxgep->niu_type)); return (NXGE_ERROR); } port_type = nxgep->niu_type >> (NXGE_PORT_TYPE_SHIFT * portn); port_type = port_type & (NXGE_PORT_TYPE_MASK); switch (port_type) { case NXGE_PORT_1G_COPPER: nxgep->mac.portmode = PORT_1G_COPPER; break; case NXGE_PORT_10G_COPPER: nxgep->mac.portmode = PORT_10G_COPPER; break; case NXGE_PORT_1G_FIBRE: nxgep->mac.portmode = PORT_1G_FIBER; break; case NXGE_PORT_10G_FIBRE: nxgep->mac.portmode = PORT_10G_FIBER; break; case NXGE_PORT_1G_SERDES: nxgep->mac.portmode = PORT_1G_SERDES; break; case NXGE_PORT_10G_SERDES: nxgep->mac.portmode = PORT_10G_SERDES; break; /* Ports 2 and 3 of Alonso or ARTM */ case NXGE_PORT_1G_RGMII_FIBER: nxgep->mac.portmode = PORT_1G_RGMII_FIBER; break; case NXGE_PORT_TN1010: /* * If this port uses the TN1010 copper * PHY, then its speed is not known yet * because nxge_scan_ports_phy could only * figure out the vendor of the PHY but * not its speed. nxge_set_tn1010_param * will read the PHY speed and set * portmode accordingly. */ if ((status = nxge_set_tn1010_param(nxgep)) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_set_tn1010_param failed")); return (status); } break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_setup_xcvr_table: " "Unknown port-type: 0x%x", port_type)); return (NXGE_ERROR); } } /* * Above switch has figured out nxge->mac.portmode, now set * nxgep->xcvr (the table) and nxgep->xcvr_addr according * to portmode. */ switch (nxgep->mac.portmode) { case PORT_1G_COPPER: case PORT_1G_RGMII_FIBER: nxgep->xcvr = nxge_1G_copper_table; nxgep->xcvr_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; /* * For Altas 4-1G copper, Xcvr port numbers are * swapped with ethernet port number. This is * designed for better signal integrity in * routing. This is also the case for the * on-board Neptune copper ports on the Maramba * platform. */ switch (nxgep->platform_type) { case P_NEPTUNE_ATLAS_4PORT: case P_NEPTUNE_MARAMBA_P0: case P_NEPTUNE_MARAMBA_P1: switch (portn) { case 0: nxgep->xcvr_addr += 3; break; case 1: nxgep->xcvr_addr += 1; break; case 2: nxgep->xcvr_addr -= 1; break; case 3: nxgep->xcvr_addr -= 3; break; default: return (NXGE_ERROR); } break; default: break; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "1G %s Xcvr", (nxgep->mac.portmode == PORT_1G_COPPER) ? "Copper" : "RGMII Fiber")); break; case PORT_10G_COPPER: nxgep->xcvr = nxge_10G_copper_table; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "10G Copper Xcvr")); break; case PORT_1G_TN1010: nxgep->xcvr = nxge_1G_tn1010_table; nxgep->xcvr_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "1G TN1010 copper Xcvr")); break; case PORT_10G_TN1010: nxgep->xcvr = nxge_10G_tn1010_table; nxgep->xcvr_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "10G TN1010 copper Xcvr")); break; case PORT_1G_FIBER: case PORT_1G_SERDES: nxgep->xcvr = nxge_1G_fiber_table; nxgep->xcvr_addr = portn; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "1G %s Xcvr", (nxgep->mac.portmode == PORT_1G_FIBER) ? "Fiber" : "Serdes")); break; case PORT_10G_FIBER: case PORT_10G_SERDES: nxgep->xcvr = nxge_10G_fiber_table; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "10G xcvr " "nxgep->nxge_hw_p->xcvr_addr[portn] = [%d] " "nxgep->xcvr_addr = [%d]", nxgep->nxge_hw_p->xcvr_addr[portn], nxgep->xcvr_addr)); if (nxgep->nxge_hw_p->xcvr_addr[portn]) { nxgep->xcvr_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; } switch (nxgep->platform_type) { case P_NEPTUNE_MARAMBA_P0: case P_NEPTUNE_MARAMBA_P1: /* * Switch off LED for corresponding copper * port */ nxge_bcm5464_link_led_off(nxgep); break; default: break; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "10G %s Xcvr", (nxgep->mac.portmode == PORT_10G_FIBER) ? "Fiber" : "Serdes")); break; case PORT_HSP_MODE: nxgep->xcvr = nxge_10G_fiber_table; nxgep->xcvr.xcvr_inuse = HSP_XCVR; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Neptune 10G Hot " "Swappable Xcvr (not present)")); break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unknown port-type: 0x%x", port_type)); return (NXGE_ERROR); } } if (nxgep->mac.portmode == PORT_10G_FIBER) { uint32_t pma_pmd_id; pma_pmd_id = nxge_get_cl45_pma_pmd_id(nxgep, nxgep->xcvr_addr); if ((pma_pmd_id & BCM_PHY_ID_MASK) == MARVELL_88X201X_PHY_ID) { chip_id = MRVL88X201X_CHIP_ID; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_setup_xcvr_table: " "Chip ID MARVELL [0x%x] for 10G xcvr", chip_id)); } else if ((status = nxge_mdio_read(nxgep, nxgep->xcvr_addr, BCM8704_PCS_DEV_ADDR, BCM8704_CHIP_ID_REG, &chip_id)) == NXGE_OK) { switch (chip_id) { case BCM8704_CHIP_ID: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_setup_xcvr_table: " "Chip ID 8704 [0x%x] for 10G xcvr", chip_id)); break; case BCM8706_CHIP_ID: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_setup_xcvr_table: " "Chip ID 8706 [0x%x] for 10G xcvr", chip_id)); break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_setup_xcvr_table: " "Unknown Chip ID [0x%x] for 10G xcvr", chip_id)); break; } } } nxgep->statsp->mac_stats.xcvr_inuse = nxgep->xcvr.xcvr_inuse; nxgep->statsp->mac_stats.xcvr_portn = nxgep->xcvr_addr; nxgep->chip_id = chip_id; /* * Get the actual device ID value returned by MDIO read. */ nxgep->statsp->mac_stats.xcvr_id = 0; pma_pmd_id = nxge_get_cl45_pma_pmd_id(nxgep, nxgep->xcvr_addr); if (nxge_is_supported_phy(pma_pmd_id, CLAUSE_45_TYPE)) { nxgep->statsp->mac_stats.xcvr_id = pma_pmd_id; } else { pcs_id = nxge_get_cl45_pcs_id(nxgep, nxgep->xcvr_addr); if (nxge_is_supported_phy(pcs_id, CLAUSE_45_TYPE)) { nxgep->statsp->mac_stats.xcvr_id = pcs_id; } else { phy_id = nxge_get_cl22_phy_id(nxgep, nxgep->xcvr_addr); if (nxge_is_supported_phy(phy_id, CLAUSE_22_TYPE)) { nxgep->statsp->mac_stats.xcvr_id = phy_id; } } } nxgep->mac.linkchkmode = LINKCHK_TIMER; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_setup_xcvr_table: niu_type" "[0x%x] platform type[0x%x] xcvr_addr[%d]", nxgep->niu_type, nxgep->platform_type, nxgep->xcvr_addr)); return (status); } /* Initialize the entire MAC and physical layer */ nxge_status_t nxge_mac_init(p_nxge_t nxgep) { uint8_t portn; nxge_status_t status = NXGE_OK; portn = NXGE_GET_PORT_NUM(nxgep->function_num); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mac_init: port<%d>", portn)); nxgep->mac.portnum = portn; nxgep->mac.porttype = PORT_TYPE_XMAC; if ((portn == BMAC_PORT_0) || (portn == BMAC_PORT_1)) nxgep->mac.porttype = PORT_TYPE_BMAC; /* Initialize XIF to configure a network mode */ if ((status = nxge_xif_init(nxgep)) != NXGE_OK) { goto fail; } if ((status = nxge_pcs_init(nxgep)) != NXGE_OK) { goto fail; } /* Initialize TX and RX MACs */ /* * Always perform XIF init first, before TX and RX MAC init */ if ((status = nxge_tx_mac_reset(nxgep)) != NXGE_OK) goto fail; if ((status = nxge_tx_mac_init(nxgep)) != NXGE_OK) goto fail; if ((status = nxge_rx_mac_reset(nxgep)) != NXGE_OK) goto fail; if ((status = nxge_rx_mac_init(nxgep)) != NXGE_OK) goto fail; if ((status = nxge_tx_mac_enable(nxgep)) != NXGE_OK) goto fail; if ((status = nxge_rx_mac_enable(nxgep)) != NXGE_OK) goto fail; /* Initialize MAC control configuration */ if ((status = nxge_mac_ctrl_init(nxgep)) != NXGE_OK) { goto fail; } nxgep->statsp->mac_stats.mac_mtu = nxgep->mac.maxframesize; /* The Neptune Serdes needs to be reinitialized again */ if ((NXGE_IS_VALID_NEPTUNE_TYPE(nxgep)) && ((nxgep->mac.portmode == PORT_1G_SERDES) || (nxgep->mac.portmode == PORT_1G_TN1010) || (nxgep->mac.portmode == PORT_1G_FIBER)) && ((portn == 0) || (portn == 1))) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_mac_init: reinit Neptune 1G Serdes ")); if ((status = nxge_1G_serdes_init(nxgep)) != NXGE_OK) { goto fail; } } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_mac_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_mac_init: failed to initialize MAC port<%d>", portn)); return (status); } /* Initialize the Ethernet Link */ nxge_status_t nxge_link_init(p_nxge_t nxgep) { nxge_status_t status = NXGE_OK; nxge_port_mode_t portmode; #ifdef NXGE_DEBUG uint8_t portn; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_link_init: port<%d>", portn)); #endif if (nxgep->hot_swappable_phy && nxgep->phy_absent) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_link_init: " "Phy not present, cannot initialize link")); return (status); } portmode = nxgep->mac.portmode; /* * Workaround to get link up in both NIU ports. Some portmodes require * that the xcvr be initialized twice, the first time before calling * nxge_serdes_init. */ if (nxgep->niu_type == N2_NIU && (portmode != PORT_10G_SERDES) && (portmode != PORT_10G_TN1010) && (portmode != PORT_1G_TN1010) && (portmode != PORT_1G_SERDES)) { if ((status = nxge_xcvr_init(nxgep)) != NXGE_OK) { goto fail; } } NXGE_DELAY(200000); /* Initialize internal serdes */ if ((status = nxge_serdes_init(nxgep)) != NXGE_OK) goto fail; NXGE_DELAY(200000); if ((status = nxge_xcvr_init(nxgep)) != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_link_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_link_init: ", "failed to initialize Ethernet link on port<%d>", portn)); return (status); } /* Initialize the XIF sub-block within the MAC */ nxge_status_t nxge_xif_init(p_nxge_t nxgep) { uint32_t xif_cfg = 0; npi_attr_t ap; uint8_t portn; nxge_port_t portt; nxge_port_mode_t portmode; p_nxge_stats_t statsp; npi_status_t rs = NPI_SUCCESS; npi_handle_t handle; portn = NXGE_GET_PORT_NUM(nxgep->function_num); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_xif_init: port<%d>", portn)); handle = nxgep->npi_handle; portmode = nxgep->mac.portmode; portt = nxgep->mac.porttype; statsp = nxgep->statsp; if ((NXGE_IS_VALID_NEPTUNE_TYPE(nxgep)) && ((nxgep->mac.portmode == PORT_1G_SERDES) || (nxgep->mac.portmode == PORT_1G_TN1010) || (nxgep->mac.portmode == PORT_1G_FIBER)) && ((portn == 0) || (portn == 1))) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_xcvr_init: set ATCA mode")); npi_mac_mif_set_atca_mode(nxgep->npi_handle, B_TRUE); } if (portt == PORT_TYPE_XMAC) { /* Setup XIF Configuration for XMAC */ if ((portmode == PORT_10G_FIBER) || (portmode == PORT_10G_COPPER) || (portmode == PORT_10G_TN1010) || (portmode == PORT_10G_SERDES)) xif_cfg |= CFG_XMAC_XIF_LFS; /* Bypass PCS so that RGMII will be used */ if (portmode == PORT_1G_COPPER) { xif_cfg |= CFG_XMAC_XIF_1G_PCS_BYPASS; } /* Set MAC Internal Loopback if necessary */ if (statsp->port_stats.lb_mode == nxge_lb_mac1000) xif_cfg |= CFG_XMAC_XIF_LOOPBACK; if (statsp->mac_stats.link_speed == 100) xif_cfg |= CFG_XMAC_XIF_SEL_CLK_25MHZ; xif_cfg |= CFG_XMAC_XIF_TX_OUTPUT; if ((portmode == PORT_10G_FIBER) || (portmode == PORT_10G_TN1010) || (portmode == PORT_1G_TN1010) || (portmode == PORT_10G_SERDES)) { /* Assume LED same for 1G and 10G */ if (statsp->mac_stats.link_up) { xif_cfg |= CFG_XMAC_XIF_LED_POLARITY; } else { xif_cfg |= CFG_XMAC_XIF_LED_FORCE; } } rs = npi_xmac_xif_config(handle, INIT, portn, xif_cfg); if (rs != NPI_SUCCESS) goto fail; nxgep->mac.xif_config = xif_cfg; /* Set Port Mode */ if ((portmode == PORT_10G_FIBER) || (portmode == PORT_10G_COPPER) || (portmode == PORT_10G_TN1010) || (portmode == PORT_10G_SERDES)) { SET_MAC_ATTR1(handle, ap, portn, MAC_PORT_MODE, MAC_XGMII_MODE, rs); if (rs != NPI_SUCCESS) goto fail; if (statsp->mac_stats.link_up) { if (nxge_10g_link_led_on(nxgep) != NXGE_OK) goto fail; } else { if (nxge_10g_link_led_off(nxgep) != NXGE_OK) goto fail; } } else if ((portmode == PORT_1G_FIBER) || (portmode == PORT_1G_COPPER) || (portmode == PORT_1G_SERDES) || (portmode == PORT_1G_TN1010) || (portmode == PORT_1G_RGMII_FIBER)) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_xif_init: Port[%d] Mode[%d] Speed[%d]", portn, portmode, statsp->mac_stats.link_speed)); if (statsp->mac_stats.link_speed == 1000) { SET_MAC_ATTR1(handle, ap, portn, MAC_PORT_MODE, MAC_GMII_MODE, rs); } else { SET_MAC_ATTR1(handle, ap, portn, MAC_PORT_MODE, MAC_MII_MODE, rs); } if (rs != NPI_SUCCESS) goto fail; } else { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_xif_init: Unknown port mode (%d)" " for port<%d>", portmode, portn)); goto fail; } /* Enable ATCA mode */ } else if (portt == PORT_TYPE_BMAC) { /* Setup XIF Configuration for BMAC */ if ((portmode == PORT_1G_COPPER) || (portmode == PORT_1G_RGMII_FIBER)) { if (statsp->mac_stats.link_speed == 100) xif_cfg |= CFG_BMAC_XIF_SEL_CLK_25MHZ; } if (statsp->port_stats.lb_mode == nxge_lb_mac1000) xif_cfg |= CFG_BMAC_XIF_LOOPBACK; if (statsp->mac_stats.link_speed == 1000) xif_cfg |= CFG_BMAC_XIF_GMII_MODE; xif_cfg |= CFG_BMAC_XIF_TX_OUTPUT; rs = npi_bmac_xif_config(handle, INIT, portn, xif_cfg); if (rs != NPI_SUCCESS) goto fail; nxgep->mac.xif_config = xif_cfg; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_xif_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_xif_init: Failed to initialize XIF port<%d>", portn)); return (NXGE_ERROR | rs); } /* * Initialize the PCS sub-block in the MAC. Note that PCS does not * support loopback like XPCS. */ nxge_status_t nxge_pcs_init(p_nxge_t nxgep) { pcs_cfg_t pcs_cfg; uint32_t val; uint8_t portn; nxge_port_mode_t portmode; npi_handle_t handle; p_nxge_stats_t statsp; pcs_ctrl_t pcs_ctrl; npi_status_t rs = NPI_SUCCESS; uint8_t i; handle = nxgep->npi_handle; portmode = nxgep->mac.portmode; portn = nxgep->mac.portnum; statsp = nxgep->statsp; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_pcs_init: port<%d>", portn)); if (portmode == PORT_1G_FIBER || portmode == PORT_1G_TN1010 || portmode == PORT_1G_SERDES) { if (portmode == PORT_1G_TN1010) { /* Reset PCS multiple time in PORT_1G_TN1010 mode */ for (i = 0; i < 6; i ++) { if ((rs = npi_mac_pcs_reset(handle, portn)) != NPI_SUCCESS) { goto fail; } } } else { if ((rs = npi_mac_pcs_reset(handle, portn)) != NPI_SUCCESS) goto fail; } /* Initialize port's PCS */ pcs_cfg.value = 0; pcs_cfg.bits.w0.enable = 1; pcs_cfg.bits.w0.mask = 1; PCS_REG_WR(handle, portn, PCS_CONFIG_REG, pcs_cfg.value); PCS_REG_WR(handle, portn, PCS_DATAPATH_MODE_REG, 0); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_pcs_init: (1G) port<%d> write config 0x%llx", portn, pcs_cfg.value)); if (portmode == PORT_1G_TN1010) { /* * Must disable PCS auto-negotiation when the the driver * is driving the TN1010 based XAUI card Otherwise the * autonegotiation between the PCS and the TN1010 PCS * will never complete and the Neptune/NIU will not work */ pcs_ctrl.value = 0; PCS_REG_WR(handle, portn, PCS_MII_CTRL_REG, pcs_ctrl.value); } } else if (portmode == PORT_10G_FIBER || portmode == PORT_10G_COPPER || portmode == PORT_10G_TN1010 || portmode == PORT_10G_SERDES) { /* Use internal XPCS, bypass 1G PCS */ XMAC_REG_RD(handle, portn, XMAC_CONFIG_REG, &val); val &= ~XMAC_XIF_XPCS_BYPASS; XMAC_REG_WR(handle, portn, XMAC_CONFIG_REG, val); if ((rs = npi_xmac_xpcs_reset(handle, portn)) != NPI_SUCCESS) goto fail; /* Set XPCS Internal Loopback if necessary */ if ((rs = npi_xmac_xpcs_read(handle, portn, XPCS_REG_CONTROL1, &val)) != NPI_SUCCESS) goto fail; if ((statsp->port_stats.lb_mode == nxge_lb_mac10g) || (statsp->port_stats.lb_mode == nxge_lb_mac1000)) val |= XPCS_CTRL1_LOOPBK; else val &= ~XPCS_CTRL1_LOOPBK; if ((rs = npi_xmac_xpcs_write(handle, portn, XPCS_REG_CONTROL1, val)) != NPI_SUCCESS) goto fail; /* Clear descw errors */ if ((rs = npi_xmac_xpcs_write(handle, portn, XPCS_REG_DESCWERR_COUNTER, 0)) != NPI_SUCCESS) goto fail; /* Clear symbol errors */ if ((rs = npi_xmac_xpcs_read(handle, portn, XPCS_REG_SYMBOL_ERR_L0_1_COUNTER, &val)) != NPI_SUCCESS) goto fail; if ((rs = npi_xmac_xpcs_read(handle, portn, XPCS_REG_SYMBOL_ERR_L2_3_COUNTER, &val)) != NPI_SUCCESS) goto fail; } else if ((portmode == PORT_1G_COPPER) || (portmode == PORT_1G_RGMII_FIBER)) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_pcs_init: (1G) copper port<%d>", portn)); if (portn < 4) { PCS_REG_WR(handle, portn, PCS_DATAPATH_MODE_REG, PCS_DATAPATH_MODE_MII); } if ((rs = npi_mac_pcs_reset(handle, portn)) != NPI_SUCCESS) goto fail; } else { goto fail; } pass: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_pcs_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_pcs_init: Failed to initialize PCS port<%d>", portn)); return (NXGE_ERROR | rs); } /* * Initialize the MAC CTRL sub-block within the MAC * Only the receive-pause-cap is supported. */ nxge_status_t nxge_mac_ctrl_init(p_nxge_t nxgep) { uint8_t portn; nxge_port_t portt; p_nxge_stats_t statsp; npi_handle_t handle; uint32_t val; portn = NXGE_GET_PORT_NUM(nxgep->function_num); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mac_ctrl_init: port<%d>", portn)); handle = nxgep->npi_handle; portt = nxgep->mac.porttype; statsp = nxgep->statsp; if (portt == PORT_TYPE_XMAC) { /* Reading the current XMAC Config Register for XMAC */ XMAC_REG_RD(handle, portn, XMAC_CONFIG_REG, &val); /* * Setup XMAC Configuration for XMAC * XMAC only supports receive-pause */ if (statsp->mac_stats.adv_cap_asmpause) { if (!statsp->mac_stats.adv_cap_pause) { /* * If adv_cap_asmpause is 1 and adv_cap_pause * is 0, enable receive pause. */ val |= XMAC_RX_CFG_RX_PAUSE_EN; } else { /* * If adv_cap_asmpause is 1 and adv_cap_pause * is 1, disable receive pause. Send pause is * not supported. */ val &= ~XMAC_RX_CFG_RX_PAUSE_EN; } } else { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mac_ctrl_init: port<%d>: pause", portn)); if (statsp->mac_stats.adv_cap_pause) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mac_ctrl_init: port<%d>: " "enable pause", portn)); /* * If adv_cap_asmpause is 0 and adv_cap_pause * is 1, enable receive pause. */ val |= XMAC_RX_CFG_RX_PAUSE_EN; } else { /* * If adv_cap_asmpause is 0 and adv_cap_pause * is 0, disable receive pause. Send pause is * not supported */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mac_ctrl_init: port<%d>: " "disable pause", portn)); val &= ~XMAC_RX_CFG_RX_PAUSE_EN; } } XMAC_REG_WR(handle, portn, XMAC_CONFIG_REG, val); } else if (portt == PORT_TYPE_BMAC) { /* Reading the current MAC CTRL Config Register for BMAC */ BMAC_REG_RD(handle, portn, MAC_CTRL_CONFIG_REG, &val); /* Setup MAC CTRL Configuration for BMAC */ if (statsp->mac_stats.adv_cap_asmpause) { if (statsp->mac_stats.adv_cap_pause) { /* * If adv_cap_asmpause is 1 and adv_cap_pause * is 1, disable receive pause. Send pause * is not supported */ val &= ~MAC_CTRL_CFG_RECV_PAUSE_EN; } else { /* * If adv_cap_asmpause is 1 and adv_cap_pause * is 0, enable receive pause and disable * send pause. */ val |= MAC_CTRL_CFG_RECV_PAUSE_EN; val &= ~MAC_CTRL_CFG_SEND_PAUSE_EN; } } else { if (statsp->mac_stats.adv_cap_pause) { /* * If adv_cap_asmpause is 0 and adv_cap_pause * is 1, enable receive pause. Send pause is * not supported. */ val |= MAC_CTRL_CFG_RECV_PAUSE_EN; } else { /* * If adv_cap_asmpause is 0 and adv_cap_pause * is 0, pause capability is not available in * either direction. */ val &= (~MAC_CTRL_CFG_SEND_PAUSE_EN & ~MAC_CTRL_CFG_RECV_PAUSE_EN); } } BMAC_REG_WR(handle, portn, MAC_CTRL_CONFIG_REG, val); } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_mac_ctrl_init: port<%d>", portn)); return (NXGE_OK); } /* Initialize the Internal Serdes */ nxge_status_t nxge_serdes_init(p_nxge_t nxgep) { p_nxge_stats_t statsp; #ifdef NXGE_DEBUG uint8_t portn; #endif nxge_status_t status = NXGE_OK; #ifdef NXGE_DEBUG portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_serdes_init port<%d>", portn)); #endif if (nxgep->xcvr.serdes_init) { statsp = nxgep->statsp; status = nxgep->xcvr.serdes_init(nxgep); if (status != NXGE_OK) goto fail; statsp->mac_stats.serdes_inits++; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_serdes_init port<%d>", portn)); return (NXGE_OK); fail: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_serdes_init: Failed to initialize serdes for port<%d>", portn)); return (status); } /* Initialize the TI Hedwig Internal Serdes (N2-NIU only) */ static nxge_status_t nxge_n2_serdes_init(p_nxge_t nxgep) { uint8_t portn; int chan; esr_ti_cfgpll_l_t pll_cfg_l; esr_ti_cfgpll_l_t pll_sts_l; esr_ti_cfgrx_l_t rx_cfg_l; esr_ti_cfgrx_h_t rx_cfg_h; esr_ti_cfgtx_l_t tx_cfg_l; esr_ti_cfgtx_h_t tx_cfg_h; #ifdef NXGE_DEBUG esr_ti_testcfg_t cfg; #endif esr_ti_testcfg_t test_cfg; nxge_status_t status = NXGE_OK; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>", portn)); tx_cfg_l.value = 0; tx_cfg_h.value = 0; rx_cfg_l.value = 0; rx_cfg_h.value = 0; pll_cfg_l.value = 0; pll_sts_l.value = 0; test_cfg.value = 0; /* * If the nxge driver has been plumbed without a link, then it will * detect a link up when a cable connecting to an anto-negotiation * partner is plugged into the port. Because the TN1010 PHY supports * both 1G and 10G speeds, the driver must re-configure the * Neptune/NIU according to the negotiated speed. nxge_n2_serdes_init * is called at the post-link-up reconfiguration time. Here it calls * nxge_set_tn1010_param to set portmode before re-initializing * the serdes. */ if (nxgep->mac.portmode == PORT_1G_TN1010 || nxgep->mac.portmode == PORT_10G_TN1010) { if (nxge_set_tn1010_param(nxgep) != NXGE_OK) { goto fail; } } if (nxgep->mac.portmode == PORT_10G_FIBER || nxgep->mac.portmode == PORT_10G_TN1010 || nxgep->mac.portmode == PORT_10G_SERDES) { /* 0x0E01 */ tx_cfg_l.bits.entx = 1; tx_cfg_l.bits.swing = CFGTX_SWING_1375MV; /* 0x9101 */ rx_cfg_l.bits.enrx = 1; rx_cfg_l.bits.term = CFGRX_TERM_0P8VDDT; rx_cfg_l.bits.align = CFGRX_ALIGN_EN; rx_cfg_l.bits.los = CFGRX_LOS_LOTHRES; /* 0x0008 */ rx_cfg_h.bits.eq = CFGRX_EQ_ADAPTIVE_LP_ADAPTIVE_ZF; /* Set loopback mode if necessary */ if (nxgep->statsp->port_stats.lb_mode == nxge_lb_serdes10g) { tx_cfg_l.bits.entest = 1; rx_cfg_l.bits.entest = 1; test_cfg.bits.loopback = TESTCFG_INNER_CML_DIS_LOOPBACK; if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_TEST_CFG_REG, test_cfg.value)) != NXGE_OK) goto fail; } /* Initialize PLL for 10G */ pll_cfg_l.bits.mpy = CFGPLL_MPY_10X; pll_cfg_l.bits.enpll = 1; pll_sts_l.bits.enpll = 1; if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_PLL_CFG_L_REG, pll_cfg_l.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_PLL_STS_L_REG, pll_sts_l.value)) != NXGE_OK) goto fail; #ifdef NXGE_DEBUG nxge_mdio_read(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_PLL_CFG_L_REG, &cfg.value); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: PLL cfg.l 0x%x (0x%x)", portn, pll_cfg_l.value, cfg.value)); nxge_mdio_read(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_PLL_STS_L_REG, &cfg.value); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: PLL sts.l 0x%x (0x%x)", portn, pll_sts_l.value, cfg.value)); #endif } else if (nxgep->mac.portmode == PORT_1G_FIBER || nxgep->mac.portmode == PORT_1G_TN1010 || nxgep->mac.portmode == PORT_1G_SERDES) { /* 0x0E21 */ tx_cfg_l.bits.entx = 1; tx_cfg_l.bits.rate = CFGTX_RATE_HALF; tx_cfg_l.bits.swing = CFGTX_SWING_1375MV; /* 0x9121 */ rx_cfg_l.bits.enrx = 1; rx_cfg_l.bits.rate = CFGRX_RATE_HALF; rx_cfg_l.bits.term = CFGRX_TERM_0P8VDDT; rx_cfg_l.bits.align = CFGRX_ALIGN_EN; rx_cfg_l.bits.los = CFGRX_LOS_LOTHRES; if (portn == 0) { /* 0x8 */ rx_cfg_h.bits.eq = CFGRX_EQ_ADAPTIVE_LP_ADAPTIVE_ZF; } /* Initialize PLL for 1G */ pll_cfg_l.bits.mpy = CFGPLL_MPY_8X; pll_cfg_l.bits.enpll = 1; pll_sts_l.bits.enpll = 1; if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_PLL_CFG_L_REG, pll_cfg_l.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_PLL_STS_L_REG, pll_sts_l.value)) != NXGE_OK) goto fail; #ifdef NXGE_DEBUG nxge_mdio_read(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_PLL_CFG_L_REG, &cfg.value); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: PLL cfg.l 0x%x (0x%x)", portn, pll_cfg_l.value, cfg.value)); nxge_mdio_read(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_PLL_STS_L_REG, &cfg.value); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: PLL sts.l 0x%x (0x%x)", portn, pll_sts_l.value, cfg.value)); #endif /* Set loopback mode if necessary */ if (nxgep->statsp->port_stats.lb_mode == nxge_lb_serdes1000) { tx_cfg_l.bits.entest = 1; rx_cfg_l.bits.entest = 1; test_cfg.bits.loopback = TESTCFG_INNER_CML_DIS_LOOPBACK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: loopback 0x%x", portn, test_cfg.value)); if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_TEST_CFG_REG, test_cfg.value)) != NXGE_OK) { goto fail; } } } else { goto fail; } /* MIF_REG_WR(handle, MIF_MASK_REG, ~mask); */ NXGE_DELAY(20); /* init TX channels */ for (chan = 0; chan < 4; chan++) { if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_TX_CFG_L_REG_ADDR(chan), tx_cfg_l.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_TX_CFG_H_REG_ADDR(chan), tx_cfg_h.value)) != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: chan %d tx_cfg_l 0x%x", portn, chan, tx_cfg_l.value)); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: chan %d tx_cfg_h 0x%x", portn, chan, tx_cfg_h.value)); } /* init RX channels */ for (chan = 0; chan < 4; chan++) { if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_RX_CFG_L_REG_ADDR(chan), rx_cfg_l.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_write(nxgep, portn, ESR_N2_DEV_ADDR, ESR_N2_RX_CFG_H_REG_ADDR(chan), rx_cfg_h.value)) != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: chan %d rx_cfg_l 0x%x", portn, chan, rx_cfg_l.value)); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_n2_serdes_init port<%d>: chan %d rx_cfg_h 0x%x", portn, chan, rx_cfg_h.value)); } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_n2_serdes_init port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_n2_serdes_init: Failed to initialize N2 serdes for port<%d>", portn)); return (status); } /* Initialize the Neptune Internal Serdes for 10G (Neptune only) */ static nxge_status_t nxge_neptune_10G_serdes_init(p_nxge_t nxgep) { npi_handle_t handle; uint8_t portn; int chan, i; sr_rx_tx_ctrl_l_t rx_tx_ctrl_l; sr_rx_tx_ctrl_h_t rx_tx_ctrl_h; sr_glue_ctrl0_l_t glue_ctrl0_l; sr_glue_ctrl0_h_t glue_ctrl0_h; uint64_t val; uint16_t val16l; uint16_t val16h; nxge_status_t status = NXGE_OK; portn = nxgep->mac.portnum; if ((portn != 0) && (portn != 1)) return (NXGE_OK); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_neptune_10G_serdes_init port<%d>", portn)); handle = nxgep->npi_handle; switch (portn) { case 0: /* Reset Serdes */ ESR_REG_WR(handle, ESR_RESET_REG, ESR_RESET_0); NXGE_DELAY(20); ESR_REG_WR(handle, ESR_RESET_REG, 0x0); NXGE_DELAY(2000); /* Configure Serdes to 10G mode */ ESR_REG_WR(handle, ESR_0_PLL_CONFIG_REG, ESR_PLL_CFG_10G_SERDES); ESR_REG_WR(handle, ESR_0_CONTROL_REG, ESR_CTL_EN_SYNCDET_0 | ESR_CTL_EN_SYNCDET_1 | ESR_CTL_EN_SYNCDET_2 | ESR_CTL_EN_SYNCDET_3 | (0x5 << ESR_CTL_OUT_EMPH_0_SHIFT) | (0x5 << ESR_CTL_OUT_EMPH_1_SHIFT) | (0x5 << ESR_CTL_OUT_EMPH_2_SHIFT) | (0x5 << ESR_CTL_OUT_EMPH_3_SHIFT) | (0x5 << ESR_CTL_OUT_EMPH_3_SHIFT) | (0x1 << ESR_CTL_LOSADJ_0_SHIFT) | (0x1 << ESR_CTL_LOSADJ_1_SHIFT) | (0x1 << ESR_CTL_LOSADJ_2_SHIFT) | (0x1 << ESR_CTL_LOSADJ_3_SHIFT)); /* Set Serdes0 Internal Loopback if necessary */ if (nxgep->statsp->port_stats.lb_mode == nxge_lb_serdes10g) { ESR_REG_WR(handle, ESR_0_TEST_CONFIG_REG, ESR_PAD_LOOPBACK_CH3 | ESR_PAD_LOOPBACK_CH2 | ESR_PAD_LOOPBACK_CH1 | ESR_PAD_LOOPBACK_CH0); } else { ESR_REG_WR(handle, ESR_0_TEST_CONFIG_REG, 0); } break; case 1: /* Reset Serdes */ ESR_REG_WR(handle, ESR_RESET_REG, ESR_RESET_1); NXGE_DELAY(20); ESR_REG_WR(handle, ESR_RESET_REG, 0x0); NXGE_DELAY(2000); /* Configure Serdes to 10G mode */ ESR_REG_WR(handle, ESR_1_PLL_CONFIG_REG, ESR_PLL_CFG_10G_SERDES); ESR_REG_WR(handle, ESR_1_CONTROL_REG, ESR_CTL_EN_SYNCDET_0 | ESR_CTL_EN_SYNCDET_1 | ESR_CTL_EN_SYNCDET_2 | ESR_CTL_EN_SYNCDET_3 | (0x5 << ESR_CTL_OUT_EMPH_0_SHIFT) | (0x5 << ESR_CTL_OUT_EMPH_1_SHIFT) | (0x5 << ESR_CTL_OUT_EMPH_2_SHIFT) | (0x5 << ESR_CTL_OUT_EMPH_3_SHIFT) | (0x5 << ESR_CTL_OUT_EMPH_3_SHIFT) | (0x1 << ESR_CTL_LOSADJ_0_SHIFT) | (0x1 << ESR_CTL_LOSADJ_1_SHIFT) | (0x1 << ESR_CTL_LOSADJ_2_SHIFT) | (0x1 << ESR_CTL_LOSADJ_3_SHIFT)); /* Set Serdes1 Internal Loopback if necessary */ if (nxgep->statsp->port_stats.lb_mode == nxge_lb_serdes10g) { ESR_REG_WR(handle, ESR_1_TEST_CONFIG_REG, ESR_PAD_LOOPBACK_CH3 | ESR_PAD_LOOPBACK_CH2 | ESR_PAD_LOOPBACK_CH1 | ESR_PAD_LOOPBACK_CH0); } else { ESR_REG_WR(handle, ESR_1_TEST_CONFIG_REG, 0); } break; default: /* Nothing to do here */ goto done; } /* init TX RX channels */ for (chan = 0; chan < 4; chan++) { if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_CONTROL_L_ADDR(chan), &rx_tx_ctrl_l.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_CONTROL_H_ADDR(chan), &rx_tx_ctrl_h.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_GLUE_CONTROL0_L_ADDR(chan), &glue_ctrl0_l.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_GLUE_CONTROL0_H_ADDR(chan), &glue_ctrl0_h.value)) != NXGE_OK) goto fail; rx_tx_ctrl_l.bits.enstretch = 1; rx_tx_ctrl_h.bits.vmuxlo = 2; rx_tx_ctrl_h.bits.vpulselo = 2; glue_ctrl0_l.bits.rxlosenable = 1; glue_ctrl0_l.bits.samplerate = 0xF; glue_ctrl0_l.bits.thresholdcount = 0xFF; glue_ctrl0_h.bits.bitlocktime = BITLOCKTIME_300_CYCLES; if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_CONTROL_L_ADDR(chan), rx_tx_ctrl_l.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_CONTROL_H_ADDR(chan), rx_tx_ctrl_h.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_GLUE_CONTROL0_L_ADDR(chan), glue_ctrl0_l.value)) != NXGE_OK) goto fail; if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_GLUE_CONTROL0_H_ADDR(chan), glue_ctrl0_h.value)) != NXGE_OK) goto fail; } /* Apply Tx core reset */ if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_L_ADDR(), (uint16_t)0)) != NXGE_OK) goto fail; if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_H_ADDR(), (uint16_t)0xffff)) != NXGE_OK) goto fail; NXGE_DELAY(200); /* Apply Rx core reset */ if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_L_ADDR(), (uint16_t)0xffff)) != NXGE_OK) goto fail; NXGE_DELAY(200); if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_H_ADDR(), (uint16_t)0)) != NXGE_OK) goto fail; NXGE_DELAY(200); if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_L_ADDR(), &val16l)) != NXGE_OK) goto fail; if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_H_ADDR(), &val16h)) != NXGE_OK) goto fail; if ((val16l != 0) || (val16h != 0)) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Failed to reset port<%d> XAUI Serdes " "(val16l 0x%x val16h 0x%x)", portn, val16l, val16h)); } if (portn == 0) { /* Wait for serdes to be ready */ for (i = 0; i < MAX_SERDES_RDY_RETRIES; i++) { ESR_REG_RD(handle, ESR_INTERNAL_SIGNALS_REG, &val); if ((val & ESR_SIG_P0_BITS_MASK) != (ESR_SIG_SERDES_RDY0_P0 | ESR_SIG_DETECT0_P0 | ESR_SIG_XSERDES_RDY_P0 | ESR_SIG_XDETECT_P0_CH3 | ESR_SIG_XDETECT_P0_CH2 | ESR_SIG_XDETECT_P0_CH1 | ESR_SIG_XDETECT_P0_CH0)) NXGE_DELAY(SERDES_RDY_WT_INTERVAL); else break; } if (i == MAX_SERDES_RDY_RETRIES) { /* * RDY signal stays low may due to the absent of the * external PHY, it is not an error condition. But still * print the message for the debugging purpose when link * stays down */ NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_neptune_10G_serdes_init: " "Serdes/signal for port<%d> not ready", portn)); goto done; } } else if (portn == 1) { /* Wait for serdes to be ready */ for (i = 0; i < MAX_SERDES_RDY_RETRIES; i++) { ESR_REG_RD(handle, ESR_INTERNAL_SIGNALS_REG, &val); if ((val & ESR_SIG_P1_BITS_MASK) != (ESR_SIG_SERDES_RDY0_P1 | ESR_SIG_DETECT0_P1 | ESR_SIG_XSERDES_RDY_P1 | ESR_SIG_XDETECT_P1_CH3 | ESR_SIG_XDETECT_P1_CH2 | ESR_SIG_XDETECT_P1_CH1 | ESR_SIG_XDETECT_P1_CH0)) NXGE_DELAY(SERDES_RDY_WT_INTERVAL); else break; } if (i == MAX_SERDES_RDY_RETRIES) { /* * RDY signal stays low may due to the absent of the * external PHY, it is not an error condition. But still * print the message for the debugging purpose when link * stays down */ NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_neptune_10G_serdes_init: " "Serdes/signal for port<%d> not ready", portn)); goto done; } } done: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_neptune_10G_serdes_init port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_neptune_10G_serdes_init: " "Failed to initialize Neptune serdes for port<%d>", portn)); return (status); } /* Initialize Neptune Internal Serdes for 1G (Neptune only) */ static nxge_status_t nxge_1G_serdes_init(p_nxge_t nxgep) { npi_handle_t handle; uint8_t portn; int chan; sr_rx_tx_ctrl_l_t rx_tx_ctrl_l; sr_rx_tx_ctrl_h_t rx_tx_ctrl_h; sr_glue_ctrl0_l_t glue_ctrl0_l; sr_glue_ctrl0_h_t glue_ctrl0_h; uint64_t val; uint16_t val16l; uint16_t val16h; nxge_status_t status = NXGE_OK; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_1G_serdes_init port<%d>", portn)); handle = nxgep->npi_handle; switch (portn) { case 0: /* Assert the reset register */ ESR_REG_RD(handle, ESR_RESET_REG, &val); val |= ESR_RESET_0; ESR_REG_WR(handle, ESR_RESET_REG, val); /* Set the PLL register to 0x79 */ ESR_REG_WR(handle, ESR_0_PLL_CONFIG_REG, ESR_PLL_CFG_1G_SERDES); /* Set the control register to 0x249249f */ ESR_REG_WR(handle, ESR_0_CONTROL_REG, ESR_CTL_1G_SERDES); /* Set Serdes0 Internal Loopback if necessary */ if (nxgep->statsp->port_stats.lb_mode == nxge_lb_serdes1000) { /* Set pad loopback modes 0xaa */ ESR_REG_WR(handle, ESR_0_TEST_CONFIG_REG, ESR_TSTCFG_LBTEST_PAD); } else { ESR_REG_WR(handle, ESR_0_TEST_CONFIG_REG, 0); } /* Deassert the reset register */ ESR_REG_RD(handle, ESR_RESET_REG, &val); val &= ~ESR_RESET_0; ESR_REG_WR(handle, ESR_RESET_REG, val); break; case 1: /* Assert the reset register */ ESR_REG_RD(handle, ESR_RESET_REG, &val); val |= ESR_RESET_1; ESR_REG_WR(handle, ESR_RESET_REG, val); /* Set PLL register to 0x79 */ ESR_REG_WR(handle, ESR_1_PLL_CONFIG_REG, ESR_PLL_CFG_1G_SERDES); /* Set the control register to 0x249249f */ ESR_REG_WR(handle, ESR_1_CONTROL_REG, ESR_CTL_1G_SERDES); /* Set Serdes1 Internal Loopback if necessary */ if (nxgep->statsp->port_stats.lb_mode == nxge_lb_serdes1000) { /* Set pad loopback mode 0xaa */ ESR_REG_WR(handle, ESR_1_TEST_CONFIG_REG, ESR_TSTCFG_LBTEST_PAD); } else { ESR_REG_WR(handle, ESR_1_TEST_CONFIG_REG, 0); } /* Deassert the reset register */ ESR_REG_RD(handle, ESR_RESET_REG, &val); val &= ~ESR_RESET_1; ESR_REG_WR(handle, ESR_RESET_REG, val); break; default: /* Nothing to do here */ goto done; } /* init TX RX channels */ for (chan = 0; chan < 4; chan++) { if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_CONTROL_L_ADDR(chan), &rx_tx_ctrl_l.value)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_CONTROL_H_ADDR(chan), &rx_tx_ctrl_h.value)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_GLUE_CONTROL0_L_ADDR(chan), &glue_ctrl0_l.value)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_GLUE_CONTROL0_H_ADDR(chan), &glue_ctrl0_h.value)) != NXGE_OK) { goto fail; } rx_tx_ctrl_l.bits.enstretch = 1; rx_tx_ctrl_h.bits.vmuxlo = 2; rx_tx_ctrl_h.bits.vpulselo = 2; glue_ctrl0_l.bits.rxlosenable = 1; glue_ctrl0_l.bits.samplerate = 0xF; glue_ctrl0_l.bits.thresholdcount = 0xFF; glue_ctrl0_h.bits.bitlocktime = BITLOCKTIME_300_CYCLES; if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_CONTROL_L_ADDR(chan), rx_tx_ctrl_l.value)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_CONTROL_H_ADDR(chan), rx_tx_ctrl_h.value)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_GLUE_CONTROL0_L_ADDR(chan), glue_ctrl0_l.value)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_GLUE_CONTROL0_H_ADDR(chan), glue_ctrl0_h.value)) != NXGE_OK) { goto fail; } } if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_POWER_CONTROL_L_ADDR(), 0xfff)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_POWER_CONTROL_H_ADDR(), 0xfff)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_TX_POWER_CONTROL_L_ADDR(), 0x70)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_TX_POWER_CONTROL_H_ADDR(), 0xfff)) != NXGE_OK) { goto fail; } /* Apply Tx core reset */ if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_L_ADDR(), (uint16_t)0)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_H_ADDR(), (uint16_t)0xffff)) != NXGE_OK) { goto fail; } NXGE_DELAY(200); /* Apply Rx core reset */ if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_L_ADDR(), (uint16_t)0xffff)) != NXGE_OK) { goto fail; } NXGE_DELAY(200); if ((status = nxge_mdio_write(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_H_ADDR(), (uint16_t)0)) != NXGE_OK) { goto fail; } NXGE_DELAY(200); if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_L_ADDR(), &val16l)) != NXGE_OK) { goto fail; } if ((status = nxge_mdio_read(nxgep, portn, ESR_NEPTUNE_DEV_ADDR, ESR_NEP_RX_TX_RESET_CONTROL_H_ADDR(), &val16h)) != NXGE_OK) { goto fail; } if ((val16l != 0) || (val16h != 0)) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Failed to reset port<%d> XAUI Serdes " "(val16l 0x%x val16h 0x%x)", portn, val16l, val16h)); status = NXGE_ERROR; goto fail; } NXGE_DELAY(200); ESR_REG_RD(handle, ESR_INTERNAL_SIGNALS_REG, &val); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_neptune_serdes_init: read internal signal reg port<%d> " "val 0x%x", portn, val)); if (portn == 0) { if ((val & ESR_SIG_P0_BITS_MASK_1G) != (ESR_SIG_SERDES_RDY0_P0 | ESR_SIG_DETECT0_P0)) { /* * RDY signal stays low may due to the absent of the * external PHY, it is not an error condition. But still * print the message for the debugging purpose when link * stays down */ NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_neptune_1G_serdes_init: " "Serdes/signal for port<%d> not ready", portn)); goto done; } } else if (portn == 1) { if ((val & ESR_SIG_P1_BITS_MASK_1G) != (ESR_SIG_SERDES_RDY0_P1 | ESR_SIG_DETECT0_P1)) { /* * RDY signal stays low may due to the absent of the * external PHY, it is not an error condition. But still * print the message for the debugging purpose when link * stays down */ NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_neptune_1G_serdes_init: " "Serdes/signal for port<%d> not ready", portn)); goto done; } } done: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_1G_serdes_init port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_1G_serdes_init: " "Failed to initialize Neptune serdes for port<%d>", portn)); return (status); } /* Initialize the BCM 8704 xcvr */ static nxge_status_t nxge_BCM8704_xcvr_init(p_nxge_t nxgep) { uint16_t val; #ifdef NXGE_DEBUG uint8_t portn; uint16_t val1; #endif uint8_t phy_port_addr; pmd_tx_control_t tx_ctl; control_t ctl; phyxs_control_t phyxs_ctl; pcs_control_t pcs_ctl; uint32_t delay = 0; optics_dcntr_t op_ctr; nxge_status_t status = NXGE_OK; #ifdef NXGE_DEBUG portn = nxgep->mac.portnum; #endif NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_BCM8704_xcvr_init: port<%d>", portn)); phy_port_addr = nxgep->statsp->mac_stats.xcvr_portn; /* Reset the transceiver */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PHYXS_ADDR, BCM8704_PHYXS_CONTROL_REG, &phyxs_ctl.value)) != NXGE_OK) goto fail; phyxs_ctl.bits.reset = 1; if ((status = nxge_mdio_write(nxgep, phy_port_addr, BCM8704_PHYXS_ADDR, BCM8704_PHYXS_CONTROL_REG, phyxs_ctl.value)) != NXGE_OK) goto fail; do { drv_usecwait(500); if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PHYXS_ADDR, BCM8704_PHYXS_CONTROL_REG, &phyxs_ctl.value)) != NXGE_OK) goto fail; delay++; } while ((phyxs_ctl.bits.reset) && (delay < 100)); if (delay == 100) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_xcvr_init: " "failed to reset Transceiver on port<%d>", portn)); status = NXGE_ERROR; goto fail; } /* Set to 0x7FBF */ ctl.value = 0; ctl.bits.res1 = 0x3F; ctl.bits.optxon_lvl = 1; ctl.bits.oprxflt_lvl = 1; ctl.bits.optrxlos_lvl = 1; ctl.bits.optxflt_lvl = 1; ctl.bits.opprflt_lvl = 1; ctl.bits.obtmpflt_lvl = 1; ctl.bits.opbiasflt_lvl = 1; ctl.bits.optxrst_lvl = 1; if ((status = nxge_mdio_write(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_CONTROL_REG, ctl.value)) != NXGE_OK) goto fail; /* Set to 0x164 */ tx_ctl.value = 0; tx_ctl.bits.tsck_lpwren = 1; tx_ctl.bits.tx_dac_txck = 0x2; tx_ctl.bits.tx_dac_txd = 0x1; tx_ctl.bits.xfp_clken = 1; if ((status = nxge_mdio_write(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_PMD_TX_CONTROL_REG, tx_ctl.value)) != NXGE_OK) goto fail; /* * According to Broadcom's instruction, SW needs to read * back these registers twice after written. */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_CONTROL_REG, &val)) != NXGE_OK) goto fail; if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_CONTROL_REG, &val)) != NXGE_OK) goto fail; if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_PMD_TX_CONTROL_REG, &val)) != NXGE_OK) goto fail; if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_PMD_TX_CONTROL_REG, &val)) != NXGE_OK) goto fail; /* Enable Tx and Rx LEDs to be driven by traffic */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_OPTICS_DIGITAL_CTRL_REG, &op_ctr.value)) != NXGE_OK) goto fail; if (NXGE_IS_XAUI_PLATFORM(nxgep)) { op_ctr.bits.gpio_sel = 0x1; } else { op_ctr.bits.gpio_sel = 0x3; } if ((status = nxge_mdio_write(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_OPTICS_DIGITAL_CTRL_REG, op_ctr.value)) != NXGE_OK) goto fail; NXGE_DELAY(1000000); /* Set BCM8704 Internal Loopback mode if necessary */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PCS_DEV_ADDR, BCM8704_PCS_CONTROL_REG, &pcs_ctl.value)) != NXGE_OK) goto fail; if (nxgep->statsp->port_stats.lb_mode == nxge_lb_phy10g) pcs_ctl.bits.loopback = 1; else pcs_ctl.bits.loopback = 0; if ((status = nxge_mdio_write(nxgep, phy_port_addr, BCM8704_PCS_DEV_ADDR, BCM8704_PCS_CONTROL_REG, pcs_ctl.value)) != NXGE_OK) goto fail; status = nxge_mdio_read(nxgep, phy_port_addr, 0x1, 0xA, &val); if (status != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "BCM8704 port<%d> Dev 1 Reg 0xA = 0x%x\n", portn, val)); status = nxge_mdio_read(nxgep, phy_port_addr, 0x3, 0x20, &val); if (status != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "BCM8704 port<%d> Dev 3 Reg 0x20 = 0x%x\n", portn, val)); status = nxge_mdio_read(nxgep, phy_port_addr, 0x4, 0x18, &val); if (status != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "BCM8704 port<%d> Dev 4 Reg 0x18 = 0x%x\n", portn, val)); #ifdef NXGE_DEBUG /* Diagnose link issue if link is not up */ status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_ANALOG_STATUS0_REG, &val); if (status != NXGE_OK) goto fail; status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_ANALOG_STATUS0_REG, &val); if (status != NXGE_OK) goto fail; status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_TX_ALARM_STATUS_REG, &val1); if (status != NXGE_OK) goto fail; status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_TX_ALARM_STATUS_REG, &val1); if (status != NXGE_OK) goto fail; if (val != 0x3FC) { if ((val == 0x43BC) && (val1 != 0)) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Cable not connected to peer or bad" " cable on port<%d>\n", portn)); } else if (val == 0x639C) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Optical module (XFP) is bad or absent" " on port<%d>\n", portn)); } } #endif NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_BCM8704_xcvr_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_BCM8704_xcvr_init: failed to initialize transceiver for " "port<%d>", nxgep->mac.portnum)); return (NXGE_ERROR); } /* Initialize the BCM 8706 Transceiver */ static nxge_status_t nxge_BCM8706_xcvr_init(p_nxge_t nxgep) { uint8_t phy_port_addr; phyxs_control_t phyxs_ctl; pcs_control_t pcs_ctl; uint32_t delay = 0; optics_dcntr_t op_ctr; nxge_status_t status = NXGE_OK; #ifdef NXGE_DEBUG uint8_t portn = nxgep->mac.portnum; #endif NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_BCM8706_xcvr_init: port<%d>", portn)); phy_port_addr = nxgep->statsp->mac_stats.xcvr_portn; /* Reset the transceiver */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PHYXS_ADDR, BCM8704_PHYXS_CONTROL_REG, &phyxs_ctl.value)) != NXGE_OK) goto fail; phyxs_ctl.bits.reset = 1; if ((status = nxge_mdio_write(nxgep, phy_port_addr, BCM8704_PHYXS_ADDR, BCM8704_PHYXS_CONTROL_REG, phyxs_ctl.value)) != NXGE_OK) goto fail; do { drv_usecwait(500); if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PHYXS_ADDR, BCM8704_PHYXS_CONTROL_REG, &phyxs_ctl.value)) != NXGE_OK) goto fail; delay++; } while ((phyxs_ctl.bits.reset) && (delay < 100)); if (delay == 100) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_xcvr_init: " "failed to reset Transceiver on port<%d>", portn)); status = NXGE_ERROR; goto fail; } NXGE_DELAY(1000000); /* Set BCM8706 Internal Loopback mode if necessary */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PCS_DEV_ADDR, BCM8704_PCS_CONTROL_REG, &pcs_ctl.value)) != NXGE_OK) goto fail; if (nxgep->statsp->port_stats.lb_mode == nxge_lb_phy10g) pcs_ctl.bits.loopback = 1; else pcs_ctl.bits.loopback = 0; if ((status = nxge_mdio_write(nxgep, phy_port_addr, BCM8704_PCS_DEV_ADDR, BCM8704_PCS_CONTROL_REG, pcs_ctl.value)) != NXGE_OK) goto fail; /* Enable Tx and Rx LEDs to be driven by traffic */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_OPTICS_DIGITAL_CTRL_REG, &op_ctr.value)) != NXGE_OK) goto fail; op_ctr.bits.gpio_sel = 0x3; op_ctr.bits.res2 = 0x1; if ((status = nxge_mdio_write(nxgep, phy_port_addr, BCM8704_USER_DEV3_ADDR, BCM8704_USER_OPTICS_DIGITAL_CTRL_REG, op_ctr.value)) != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_BCM8706_xcvr_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_BCM8706_xcvr_init: failed to initialize transceiver for " "port<%d>", nxgep->mac.portnum)); return (status); } #define CHK_STAT(x) status = (x); if (status != NXGE_OK) goto fail #define MRVL88X2011_RD(nxgep, port, d, r, p) \ CHK_STAT(nxge_mdio_read(nxgep, port, d, r, p)) #define MRVL88X2011_WR(nxgep, port, d, r, p) \ CHK_STAT(nxge_mdio_write(nxgep, port, d, r, p)) static void nxge_mrvl88x2011_led_blink_rate(p_nxge_t nxgep, uint16_t rate) { uint16_t value; uint8_t phy = nxgep->statsp->mac_stats.xcvr_portn; if (nxge_mdio_read(nxgep, phy, MRVL_88X2011_USER_DEV2_ADDR, MRVL_88X2011_LED_BLINK_CTL, &value) == NXGE_OK) { value &= ~MRVL_88X2011_LED_BLK_MASK; value |= (rate << MRVL_88X2011_LED_BLK_SHIFT); (void) nxge_mdio_write(nxgep, phy, MRVL_88X2011_USER_DEV2_ADDR, MRVL_88X2011_LED_BLINK_CTL, value); } } static nxge_status_t nxge_mrvl88x2011_setup_lb(p_nxge_t nxgep) { nxge_status_t status; pcs_control_t pcs_ctl; uint8_t phy = nxgep->statsp->mac_stats.xcvr_portn; MRVL88X2011_RD(nxgep, phy, MRVL_88X2011_USER_DEV3_ADDR, MRVL_88X2011_PMA_PMD_CTL_1, &pcs_ctl.value); if (nxgep->statsp->port_stats.lb_mode == nxge_lb_phy10g) pcs_ctl.bits.loopback = 1; else pcs_ctl.bits.loopback = 0; MRVL88X2011_WR(nxgep, phy, MRVL_88X2011_USER_DEV3_ADDR, MRVL_88X2011_PMA_PMD_CTL_1, pcs_ctl.value); fail: return (status); } static void nxge_mrvl88x2011_led(p_nxge_t nxgep, uint16_t val) { uint16_t val2; uint8_t phy = nxgep->statsp->mac_stats.xcvr_portn; val2 = MRVL_88X2011_LED(MRVL_88X2011_LED_ACT, val); val2 &= ~MRVL_88X2011_LED(MRVL_88X2011_LED_ACT, MRVL_88X2011_LED_CTL_MASK); val2 |= MRVL_88X2011_LED(MRVL_88X2011_LED_ACT, val); if (nxge_mdio_write(nxgep, phy, MRVL_88X2011_USER_DEV2_ADDR, MRVL_88X2011_LED_8_TO_11_CTL, val2) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mrvl88x2011_led: nxge_mdio_write failed!!")); } } static nxge_status_t nxge_mrvl88x2011_xcvr_init(p_nxge_t nxgep) { uint8_t phy; nxge_status_t status; uint16_t clk; phy = nxgep->statsp->mac_stats.xcvr_portn; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mrvl88x2011_xcvr_init: port<%d> addr<0x%x>", nxgep->mac.portnum, phy)); /* Set LED functions */ nxge_mrvl88x2011_led_blink_rate(nxgep, MRVL_88X2011_LED_BLK134MS); /* PCS activity */ nxge_mrvl88x2011_led(nxgep, MRVL_88X2011_LED_ACT); MRVL88X2011_RD(nxgep, phy, MRVL_88X2011_USER_DEV3_ADDR, MRVL_88X2011_GEN_CTL, &clk); clk |= MRVL_88X2011_ENA_XFPREFCLK; MRVL88X2011_WR(nxgep, phy, MRVL_88X2011_USER_DEV3_ADDR, MRVL_88X2011_GEN_CTL, clk); /* Set internal loopback mode if necessary */ CHK_STAT(nxge_mrvl88x2011_setup_lb(nxgep)); /* Enable PMD */ MRVL88X2011_WR(nxgep, phy, MRVL_88X2011_USER_DEV1_ADDR, MRVL_88X2011_10G_PMD_TX_DIS, MRVL_88X2011_ENA_PMDTX); NXGE_DEBUG_MSG((nxgep, MAC_CTL, " nxge_mrvl88x2011_reset: OK")); fail: return (status); } /* Initialize the 10G Transceiver */ static nxge_status_t nxge_10G_xcvr_init(p_nxge_t nxgep) { p_nxge_stats_t statsp; p_nxge_param_t param_arr = nxgep->param_arr; nxge_status_t status = NXGE_OK; #ifdef NXGE_DEBUG uint8_t portn = nxgep->mac.portnum; #endif NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_10G_xcvr_init: port<%d>", portn)); statsp = nxgep->statsp; if (nxgep->mac.portmode == PORT_10G_SERDES) { goto done; } /* Disable Link LEDs */ if (nxge_10g_link_led_off(nxgep) != NXGE_OK) goto fail; /* Set Clause 45 */ npi_mac_mif_set_indirect_mode(nxgep->npi_handle, B_TRUE); switch (nxgep->chip_id) { case BCM8704_CHIP_ID: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_10G_xcvr_init: " "Chip ID 8704 [0x%x] for 10G xcvr", nxgep->chip_id)); status = nxge_BCM8704_xcvr_init(nxgep); break; case BCM8706_CHIP_ID: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_10G_xcvr_init: " "Chip ID 8706 [0x%x] for 10G xcvr", nxgep->chip_id)); status = nxge_BCM8706_xcvr_init(nxgep); break; case MRVL88X201X_CHIP_ID: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_10G_xcvr_init: " "Chip ID 8706 [0x%x] for 10G xcvr", nxgep->chip_id)); status = nxge_mrvl88x2011_xcvr_init(nxgep); break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_xcvr_init: " "Unknown chip ID 0x%x for 10G xcvr addr[%d]", nxgep->chip_id, nxgep->statsp->mac_stats.xcvr_portn)); goto fail; } if (status != NXGE_OK) { goto fail; } done: statsp->mac_stats.cap_10gfdx = 1; statsp->mac_stats.lp_cap_10gfdx = 1; statsp->mac_stats.adv_cap_asmpause = param_arr[param_anar_asmpause].value; statsp->mac_stats.adv_cap_pause = param_arr[param_anar_pause].value; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_10G_xcvr_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_10G_xcvr_init: failed to initialize transceiver for " "port<%d>", nxgep->mac.portnum)); return (NXGE_ERROR); } /* Initialize the 1G copper (BCM 5464) Transceiver */ static nxge_status_t nxge_1G_xcvr_init(p_nxge_t nxgep) { p_nxge_param_t param_arr = nxgep->param_arr; p_nxge_stats_t statsp = nxgep->statsp; nxge_status_t status = NXGE_OK; if (nxgep->mac.portmode == PORT_1G_SERDES) { statsp->mac_stats.cap_1000fdx = param_arr[param_anar_1000fdx].value; goto done; } /* Set Clause 22 */ npi_mac_mif_set_indirect_mode(nxgep->npi_handle, B_FALSE); /* Set capability flags */ statsp->mac_stats.cap_1000fdx = param_arr[param_anar_1000fdx].value; if ((nxgep->mac.portmode == PORT_1G_COPPER) || (nxgep->mac.portmode == PORT_1G_FIBER)) { statsp->mac_stats.cap_100fdx = param_arr[param_anar_100fdx].value; statsp->mac_stats.cap_10fdx = param_arr[param_anar_10fdx].value; } status = nxge_mii_xcvr_init(nxgep); done: return (status); } /* * Although the Teranetics copper transceiver (TN1010) does not need * to be initialized by the driver for passing packets, this funtion * initializes the members of nxgep->statsp->mac_stats struct for * kstat based on the value of nxgep->statsp->ports_stats.lb_mode. * It also configures the TN1010 for PHY loopback to support SunVTS. * * TN1010 only has the option to disable advertisement for the 10G * mode. So we can set it to either Dual Mode or 1G Only mode but * can't set it to 10G Only mode. * * ndd -set command can set the following 6 speed/duplex related parameters. * * ---------------------------------------------------------------- * ndd -set /dev/nxgeX param n kstat nxge:X | grep param * ---------------------------------------------------------------- * adv_autoneg_cap kstat nxge:1 | grep adv_cap_autoneg * adv_10gfdx_cap * adv_1000fdx_cap kstat nxge:1 | grep adv_cap_1000fdx * adv_100fdx_cap kstat nxge:1 | grep adv_cap_100fdx * adv_10fdx_cap kstat nxge:1 | grep adv_cap_10fdx * adv_pause_cap kstat nxge:1 | grep adv_cap_pause * ---------------------------------------------------------------- */ static nxge_status_t nxge_tn1010_xcvr_init(p_nxge_t nxgep) { p_nxge_param_t param_arr; p_nxge_stats_t statsp; tn1010_pcs_ctrl_t tn1010_pcs_ctrl; uint16_t speed; uint8_t phy_port_addr; uint8_t portn = NXGE_GET_PORT_NUM(nxgep->function_num); int status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_1G_tn1010_xcvr_init")); param_arr = nxgep->param_arr; statsp = nxgep->statsp; /* * Initialize the xcvr statistics which are NOT controlled by ndd */ statsp->mac_stats.cap_autoneg = 1; /* TN1010 autoneg is always on */ statsp->mac_stats.cap_100T4 = 0; /* * Read the TN1010 link speed and initialize capabilities kstat. Note * that function nxge_check_tn1010_link repeatedly invoked by the * timer will update link_speed real time. */ if (nxge_get_tn1010_speed(nxgep, &speed) != NXGE_OK) { goto fail; } if (speed == TN1010_SPEED_1G) { statsp->mac_stats.cap_10gfdx = 0; } else { statsp->mac_stats.cap_10gfdx = 1; } /* Whether we are in 1G or 10G mode, we always have the 1G capability */ statsp->mac_stats.cap_1000fdx = 1; /* TN1010 is not able to operate in the following states */ statsp->mac_stats.cap_1000hdx = 0; statsp->mac_stats.cap_100fdx = 0; statsp->mac_stats.cap_100hdx = 0; statsp->mac_stats.cap_10fdx = 0; statsp->mac_stats.cap_10hdx = 0; /* param_anar_pause can be modified by ndd -set */ statsp->mac_stats.cap_pause = param_arr[param_anar_pause].value; /* * The following 4 lines actually overwrites what ever the ndd command * has set. For example, by command * ndd -set /dev/nxge1 adv_autoneg_cap n (n = 0 or 1) * we could set param_arr[param_autoneg].value to n. However, because * here we assign constants to these parameters, whatever we set with * the "ndd -set" command will be replaced. So command * kstat nxge:X | grep param * will always show those constant values. In other words, the * "ndd -set" command can NOT change the values of these 4 parameters * even though the command appears to be successful. * * Note: TN1010 auto negotiation is always enabled. */ statsp->mac_stats.adv_cap_autoneg = param_arr[param_autoneg].value = 1; statsp->mac_stats.adv_cap_1000fdx = param_arr[param_anar_1000fdx].value = 1; statsp->mac_stats.adv_cap_100fdx = param_arr[param_anar_100fdx].value = 0; statsp->mac_stats.adv_cap_10fdx = param_arr[param_anar_10fdx].value = 0; /* * The following 4 ndd params have type NXGE_PARAM_MAC_DONT_SHOW as * defined in nxge_param_arr[], therefore they are not seen by the * "ndd -get" command and can not be changed by ndd. We just set * them (both ndd param and kstat values) to constant 0 because TN1010 * does not support those speeds. */ statsp->mac_stats.adv_cap_100T4 = param_arr[param_anar_100T4].value = 0; statsp->mac_stats.adv_cap_1000hdx = param_arr[param_anar_1000hdx].value = 0; statsp->mac_stats.adv_cap_100hdx = param_arr[param_anar_100hdx].value = 0; statsp->mac_stats.adv_cap_10hdx = param_arr[param_anar_10hdx].value = 0; /* * adv_cap_pause has type NXGE_PARAM_MAC_RW, so it can be modified * by ndd */ statsp->mac_stats.adv_cap_pause = param_arr[param_anar_pause].value; /* * nxge_param_arr[] defines the adv_cap_asmpause with type * NXGE_PARAM_DONT_SHOW, therefore they are NOT seen by the * "ndd -get" command and can not be changed by ndd. Here we do not * assign a constant to it so the default value defined in * nxge_param_arr[] will be used to set the parameter and * will be shown by the kstat. */ statsp->mac_stats.adv_cap_asmpause = param_arr[param_anar_asmpause].value; /* * Initialize the link statistics. */ statsp->mac_stats.link_T4 = 0; statsp->mac_stats.link_asmpause = 0; statsp->mac_stats.link_pause = 0; if (speed == TN1010_SPEED_1G) { statsp->mac_stats.link_speed = 1000; statsp->mac_stats.link_duplex = 2; /* Full duplex */ statsp->mac_stats.link_up = 1; } else { statsp->mac_stats.link_speed = 10000; statsp->mac_stats.link_duplex = 2; statsp->mac_stats.link_up = 1; } /* * Because TN1010 does not have a link partner register, to * figure out the link partner's capabilities is tricky. Here we * just set the kstat based on our knowledge about the partner * (The partner must support auto-neg because auto-negotiation * has completed, it must support 1G or 10G because that is the * negotiated speed we are using.) * * Note: Current kstat does not show lp_cap_10gfdx and * lp_cap_10ghdx. */ if (speed == TN1010_SPEED_1G) { statsp->mac_stats.lp_cap_1000fdx = 1; statsp->mac_stats.lp_cap_10gfdx = 0; } else { statsp->mac_stats.lp_cap_1000fdx = 0; statsp->mac_stats.lp_cap_10gfdx = 1; } statsp->mac_stats.lp_cap_10ghdx = 0; statsp->mac_stats.lp_cap_1000hdx = 0; statsp->mac_stats.lp_cap_100fdx = 0; statsp->mac_stats.lp_cap_100hdx = 0; statsp->mac_stats.lp_cap_10fdx = 0; statsp->mac_stats.lp_cap_10hdx = 0; statsp->mac_stats.lp_cap_10gfdx = 0; statsp->mac_stats.lp_cap_10ghdx = 0; statsp->mac_stats.lp_cap_100T4 = 0; statsp->mac_stats.lp_cap_autoneg = 1; statsp->mac_stats.lp_cap_asmpause = 0; statsp->mac_stats.lp_cap_pause = 0; /* Handle PHY loopback for SunVTS loopback test */ npi_mac_mif_set_indirect_mode(nxgep->npi_handle, B_TRUE); phy_port_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; if ((status = nxge_mdio_read(nxgep, phy_port_addr, TN1010_PCS_DEV_ADDR, TN1010_PCS_CONTROL_REG, &tn1010_pcs_ctrl.value)) != NXGE_OK) { goto fail; } if ((statsp->port_stats.lb_mode == nxge_lb_phy1000) || (statsp->port_stats.lb_mode == nxge_lb_phy10g)) { tn1010_pcs_ctrl.bits.loopback = 1; } else { tn1010_pcs_ctrl.bits.loopback = 0; } if ((status = nxge_mdio_write(nxgep, phy_port_addr, TN1010_PCS_DEV_ADDR, TN1010_PCS_CONTROL_REG, tn1010_pcs_ctrl.value)) != NXGE_OK) { goto fail; } statsp->mac_stats.xcvr_inits++; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_1G_tn1010_xcvr_init status 0x%x", status)); return (status); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_1G_tn1010_xcvr_init status 0x%x", status)); return (status); } /* Initialize transceiver */ nxge_status_t nxge_xcvr_init(p_nxge_t nxgep) { p_nxge_stats_t statsp; #ifdef NXGE_DEBUG uint8_t portn; #endif nxge_status_t status = NXGE_OK; #ifdef NXGE_DEBUG portn = nxgep->mac.portnum; #endif NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_xcvr_init: port<%d>", portn)); statsp = nxgep->statsp; /* * Initialize the xcvr statistics. nxgep->xcvr.xcvr_init will * modify mac_stats. */ statsp->mac_stats.cap_autoneg = 0; statsp->mac_stats.cap_100T4 = 0; statsp->mac_stats.cap_100fdx = 0; statsp->mac_stats.cap_100hdx = 0; statsp->mac_stats.cap_10fdx = 0; statsp->mac_stats.cap_10hdx = 0; statsp->mac_stats.cap_asmpause = 0; statsp->mac_stats.cap_pause = 0; statsp->mac_stats.cap_1000fdx = 0; statsp->mac_stats.cap_1000hdx = 0; statsp->mac_stats.cap_10gfdx = 0; statsp->mac_stats.cap_10ghdx = 0; /* * Initialize the link statistics. */ statsp->mac_stats.link_T4 = 0; statsp->mac_stats.link_asmpause = 0; statsp->mac_stats.link_pause = 0; if (nxgep->xcvr.xcvr_init) { status = nxgep->xcvr.xcvr_init(nxgep); if (status != NXGE_OK) goto fail; statsp->mac_stats.xcvr_inits++; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_xcvr_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_xcvr_init: failed to initialize transceiver for port<%d>", portn)); return (status); } /* Look for transceiver type */ nxge_status_t nxge_xcvr_find(p_nxge_t nxgep) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_xcvr_find: port<%d>", nxgep->mac.portnum)); if (nxge_get_xcvr_type(nxgep) != NXGE_OK) return (NXGE_ERROR); if (nxge_setup_xcvr_table(nxgep) != NXGE_OK) return (NXGE_ERROR); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_xcvr_find: xcvr_inuse = %d", nxgep->statsp->mac_stats.xcvr_inuse)); return (NXGE_OK); } /* Initialize the TxMAC sub-block */ nxge_status_t nxge_tx_mac_init(p_nxge_t nxgep) { npi_attr_t ap; uint8_t portn; nxge_port_mode_t portmode; nxge_port_t portt; npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; portn = NXGE_GET_PORT_NUM(nxgep->function_num); portt = nxgep->mac.porttype; handle = nxgep->npi_handle; portmode = nxgep->mac.portmode; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_tx_mac_init: port<%d>", portn)); /* Set Max and Min Frame Size */ /* * Use maxframesize to configure the hardware maxframe size * and minframesize to configure the hardware minframe size. */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_tx_mac_init: port<%d> " "min framesize %d max framesize %d ", nxgep->mac.minframesize, nxgep->mac.maxframesize, portn)); SET_MAC_ATTR2(handle, ap, portn, MAC_PORT_FRAME_SIZE, nxgep->mac.minframesize, nxgep->mac.maxframesize, rs); if (rs != NPI_SUCCESS) goto fail; if (portt == PORT_TYPE_XMAC) { if ((rs = npi_xmac_tx_iconfig(handle, INIT, portn, 0)) != NPI_SUCCESS) goto fail; nxgep->mac.tx_iconfig = NXGE_XMAC_TX_INTRS; if ((portmode == PORT_10G_FIBER) || (portmode == PORT_10G_COPPER) || (portmode == PORT_10G_TN1010) || (portmode == PORT_10G_SERDES)) { SET_MAC_ATTR1(handle, ap, portn, XMAC_10G_PORT_IPG, XGMII_IPG_12_15, rs); if (rs != NPI_SUCCESS) goto fail; nxgep->mac.ipg[0] = XGMII_IPG_12_15; } else { SET_MAC_ATTR1(handle, ap, portn, XMAC_PORT_IPG, MII_GMII_IPG_12, rs); if (rs != NPI_SUCCESS) goto fail; nxgep->mac.ipg[0] = MII_GMII_IPG_12; } if ((rs = npi_xmac_tx_config(handle, INIT, portn, CFG_XMAC_TX_CRC | CFG_XMAC_TX)) != NPI_SUCCESS) goto fail; nxgep->mac.tx_config = CFG_XMAC_TX_CRC | CFG_XMAC_TX; nxgep->mac.maxburstsize = 0; /* not programmable */ nxgep->mac.ctrltype = 0; /* not programmable */ nxgep->mac.pa_size = 0; /* not programmable */ if ((rs = npi_xmac_zap_tx_counters(handle, portn)) != NPI_SUCCESS) goto fail; } else { if ((rs = npi_bmac_tx_iconfig(handle, INIT, portn, 0)) != NPI_SUCCESS) goto fail; nxgep->mac.tx_iconfig = NXGE_BMAC_TX_INTRS; SET_MAC_ATTR1(handle, ap, portn, BMAC_PORT_CTRL_TYPE, 0x8808, rs); if (rs != NPI_SUCCESS) goto fail; nxgep->mac.ctrltype = 0x8808; SET_MAC_ATTR1(handle, ap, portn, BMAC_PORT_PA_SIZE, 0x7, rs); if (rs != NPI_SUCCESS) goto fail; nxgep->mac.pa_size = 0x7; if ((rs = npi_bmac_tx_config(handle, INIT, portn, CFG_BMAC_TX_CRC | CFG_BMAC_TX)) != NPI_SUCCESS) goto fail; nxgep->mac.tx_config = CFG_BMAC_TX_CRC | CFG_BMAC_TX; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_tx_mac_init: port<%d>", portn)); return (NXGE_OK); fail: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_tx_mac_init: failed to initialize port<%d> TXMAC", portn)); return (NXGE_ERROR | rs); } int nxge_hio_hostinfo_get_rdc_table(p_nxge_t nxgep) { int rdc_tbl; /* * Get an RDC table (version 0). */ if ((rdc_tbl = nxge_fzc_rdc_tbl_bind(nxgep, -1, B_FALSE)) < 0) { NXGE_ERROR_MSG((nxgep, OBP_CTL, "nxge_hio_hostinfo_get_rdc_table: " "there are no free RDC tables!")); return (EBUSY); } return (rdc_tbl); } /* * nxge_hio_hostinfo_init * * Initialize an alternate MAC address, and bind a macrdctbln to it. * * Arguments: * nxge * vr The Virtualization Region * macaddr The alternate MAC address * * Notes: * 1. Find & bind an RDC table to . * 2. Program an alternate MAC address (). * 3. Bind the RDC table to . * * Context: * Service domain * * Side Effects: * nxge->class_config.mac_host_info[slot].rdctbl * vr->slot & vr->altmac * */ int nxge_hio_hostinfo_init( nxge_t *nxge, nxge_hio_vr_t *vr, /* Virtualization Region */ ether_addr_t *macaddr) /* The alternate MAC address */ { int rdc_tbl, slot; nxge_class_pt_cfg_t *class; hostinfo_t mac_rdc; npi_mac_addr_t altmac; nxge_mmac_t *mmac_info; nxge_rdc_grp_t *group; uint8_t *addr = (uint8_t *)macaddr; mutex_enter(nxge->genlock); rdc_tbl = vr->rdc_tbl; /* Initialize the NXGE RDC table data structure. */ group = &nxge->pt_config.rdc_grps[rdc_tbl]; group->port = NXGE_GET_PORT_NUM(nxge->function_num); group->config_method = RDC_TABLE_ENTRY_METHOD_REP; group->flag = 1; /* This group has been configured. */ mmac_info = &nxge->nxge_mmac_info; /* * Are there free slots. */ if (mmac_info->naddrfree == 0) { mutex_exit(nxge->genlock); return (ENOSPC); } /* * The vswitch has already added this MAC address. * Find its assigned slot. */ if (mmac_info->num_factory_mmac < mmac_info->num_mmac) { for (slot = mmac_info->num_factory_mmac + 1; slot <= mmac_info->num_mmac; slot++) { if (!(mmac_info->mac_pool[slot].flags & MMAC_SLOT_USED)) break; } if (slot > mmac_info->num_mmac) { for (slot = 1; slot <= mmac_info->num_factory_mmac; slot++) { if (!(mmac_info->mac_pool[slot].flags & MMAC_SLOT_USED)) break; } } } else { for (slot = 1; slot <= mmac_info->num_mmac; slot++) { if (!(mmac_info->mac_pool[slot].flags & MMAC_SLOT_USED)) break; } } ASSERT(slot <= mmac_info->num_mmac); vr->slot = slot; slot = vr->slot - 1; /* * Program the mac address. */ altmac.w2 = (((uint16_t)addr[0]) << 8) | (((uint16_t)addr[1]) & 0x0ff); altmac.w1 = (((uint16_t)addr[2]) << 8) | (((uint16_t)addr[3]) & 0x0ff); altmac.w0 = (((uint16_t)addr[4]) << 8) | (((uint16_t)addr[5]) & 0x0ff); if (npi_mac_altaddr_entry(nxge->npi_handle, OP_SET, nxge->function_num, slot, &altmac) != NPI_SUCCESS) { mutex_exit(nxge->genlock); return (EIO); } /* * Associate with this MAC address slot. */ class = (p_nxge_class_pt_cfg_t)&nxge->class_config; /* Update this variable. */ class = (p_nxge_class_pt_cfg_t)&nxge->class_config; class->mac_host_info[slot].rdctbl = (uint8_t)rdc_tbl; mac_rdc.value = 0; mac_rdc.bits.w0.rdc_tbl_num = rdc_tbl; mac_rdc.bits.w0.mac_pref = class->mac_host_info[slot].mpr_npr; /* had better be 1! */ /* Program the RDC table. */ if ((npi_mac_hostinfo_entry(nxge->npi_handle, OP_SET, nxge->function_num, slot, &mac_rdc)) != NPI_SUCCESS) { mutex_exit(nxge->genlock); (void) nxge_m_mmac_remove(nxge, vr->slot); return (EIO); } if (nxge->mac.portnum != XMAC_PORT_0 && nxge->mac.portnum != XMAC_PORT_1) slot++; /* (Re-)enable the MAC address. */ (void) npi_mac_altaddr_enable( nxge->npi_handle, nxge->mac.portnum, slot); bcopy(macaddr, vr->altmac, sizeof (vr->altmac)); /* * Update mmac */ bcopy(addr, mmac_info->mac_pool[vr->slot].addr, ETHERADDRL); mmac_info->mac_pool[vr->slot].flags |= MMAC_SLOT_USED; mmac_info->mac_pool[vr->slot].flags &= ~MMAC_VENDOR_ADDR; mmac_info->naddrfree--; nxge_mmac_kstat_update(nxge, vr->slot, B_FALSE); mutex_exit(nxge->genlock); return (0); } /* * nxge_hio_hostinfo_uninit * * Uninitialize an alternate MAC address. * * Arguments: * nxge * vr The Virtualization Region * * Notes: * 1. Remove the VR's alternate MAC address. * 1. Free (unbind) the RDC table allocated to this VR. * * Context: * Service domain * * Side Effects: * nxge->class_config.mac_host_info[slot].rdctbl * */ void nxge_hio_hostinfo_uninit( nxge_t *nxge, nxge_hio_vr_t *vr) { nxge_class_pt_cfg_t *class; (void) npi_mac_altaddr_disable( nxge->npi_handle, nxge->mac.portnum, vr->slot); /* Set this variable to its default. */ class = (p_nxge_class_pt_cfg_t)&nxge->class_config; class->mac_host_info[vr->slot].rdctbl = nxge->pt_config.hw_config.def_mac_rxdma_grpid; (void) nxge_m_mmac_remove(nxge, vr->slot); vr->slot = -1; (void) nxge_fzc_rdc_tbl_unbind(nxge, vr->rdc_tbl); vr->rdc_tbl = -1; } /* Initialize the RxMAC sub-block */ nxge_status_t nxge_rx_mac_init(p_nxge_t nxgep) { npi_attr_t ap; uint32_t i; uint16_t hashtab_e; p_hash_filter_t hash_filter; nxge_port_t portt; uint8_t portn; npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; uint16_t *addr16p; uint16_t addr0, addr1, addr2; xmac_rx_config_t xconfig; bmac_rx_config_t bconfig; portn = NXGE_GET_PORT_NUM(nxgep->function_num); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_rx_mac_init: port<%d>\n", portn)); handle = nxgep->npi_handle; portt = nxgep->mac.porttype; addr16p = (uint16_t *)nxgep->ouraddr.ether_addr_octet; addr0 = ntohs(addr16p[2]); addr1 = ntohs(addr16p[1]); addr2 = ntohs(addr16p[0]); SET_MAC_ATTR3(handle, ap, portn, MAC_PORT_ADDR, addr0, addr1, addr2, rs); if (rs != NPI_SUCCESS) goto fail; SET_MAC_ATTR3(handle, ap, portn, MAC_PORT_ADDR_FILTER, 0, 0, 0, rs); if (rs != NPI_SUCCESS) goto fail; SET_MAC_ATTR2(handle, ap, portn, MAC_PORT_ADDR_FILTER_MASK, 0, 0, rs); if (rs != NPI_SUCCESS) goto fail; /* * Load the multicast hash filter bits. */ hash_filter = nxgep->hash_filter; for (i = 0; i < MAC_MAX_HASH_ENTRY; i++) { if (hash_filter != NULL) { hashtab_e = (uint16_t)hash_filter->hash_filter_regs[ (NMCFILTER_REGS - 1) - i]; } else { hashtab_e = 0; } if ((rs = npi_mac_hashtab_entry(handle, OP_SET, portn, i, (uint16_t *)&hashtab_e)) != NPI_SUCCESS) goto fail; } if (portt == PORT_TYPE_XMAC) { if ((rs = npi_xmac_rx_iconfig(handle, INIT, portn, 0)) != NPI_SUCCESS) goto fail; nxgep->mac.rx_iconfig = NXGE_XMAC_RX_INTRS; (void) nxge_fflp_init_hostinfo(nxgep); xconfig = CFG_XMAC_RX_ERRCHK | CFG_XMAC_RX_CRC_CHK | CFG_XMAC_RX | CFG_XMAC_RX_CODE_VIO_CHK & ~CFG_XMAC_RX_STRIP_CRC; if (nxgep->filter.all_phys_cnt != 0) xconfig |= CFG_XMAC_RX_PROMISCUOUS; if (nxgep->filter.all_multicast_cnt != 0) xconfig |= CFG_XMAC_RX_PROMISCUOUSGROUP; xconfig |= CFG_XMAC_RX_HASH_FILTER; if ((rs = npi_xmac_rx_config(handle, INIT, portn, xconfig)) != NPI_SUCCESS) goto fail; nxgep->mac.rx_config = xconfig; /* Comparison of mac unique address is always enabled on XMAC */ if ((rs = npi_xmac_zap_rx_counters(handle, portn)) != NPI_SUCCESS) goto fail; } else { (void) nxge_fflp_init_hostinfo(nxgep); if (npi_bmac_rx_iconfig(nxgep->npi_handle, INIT, portn, 0) != NPI_SUCCESS) goto fail; nxgep->mac.rx_iconfig = NXGE_BMAC_RX_INTRS; bconfig = CFG_BMAC_RX_DISCARD_ON_ERR | CFG_BMAC_RX & ~CFG_BMAC_RX_STRIP_CRC; if (nxgep->filter.all_phys_cnt != 0) bconfig |= CFG_BMAC_RX_PROMISCUOUS; if (nxgep->filter.all_multicast_cnt != 0) bconfig |= CFG_BMAC_RX_PROMISCUOUSGROUP; bconfig |= CFG_BMAC_RX_HASH_FILTER; if ((rs = npi_bmac_rx_config(handle, INIT, portn, bconfig)) != NPI_SUCCESS) goto fail; nxgep->mac.rx_config = bconfig; /* Always enable comparison of mac unique address */ if ((rs = npi_mac_altaddr_enable(handle, portn, 0)) != NPI_SUCCESS) goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_rx_mac_init: port<%d>\n", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rx_mac_init: Failed to Initialize port<%d> RxMAC", portn)); return (NXGE_ERROR | rs); } /* Enable TXMAC */ nxge_status_t nxge_tx_mac_enable(p_nxge_t nxgep) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; nxge_status_t status = NXGE_OK; handle = nxgep->npi_handle; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_tx_mac_enable: port<%d>", nxgep->mac.portnum)); if ((status = nxge_tx_mac_init(nxgep)) != NXGE_OK) goto fail; /* based on speed */ nxgep->msg_min = ETHERMIN; if (nxgep->mac.porttype == PORT_TYPE_XMAC) { if ((rs = npi_xmac_tx_config(handle, ENABLE, nxgep->mac.portnum, CFG_XMAC_TX)) != NPI_SUCCESS) goto fail; } else { if ((rs = npi_bmac_tx_config(handle, ENABLE, nxgep->mac.portnum, CFG_BMAC_TX)) != NPI_SUCCESS) goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_tx_mac_enable: port<%d>", nxgep->mac.portnum)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxgep_tx_mac_enable: Failed to enable port<%d> TxMAC", nxgep->mac.portnum)); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); else return (status); } /* Disable TXMAC */ nxge_status_t nxge_tx_mac_disable(p_nxge_t nxgep) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; if (isLDOMguest(nxgep)) return (NXGE_OK); handle = nxgep->npi_handle; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_tx_mac_disable: port<%d>", nxgep->mac.portnum)); if (nxgep->mac.porttype == PORT_TYPE_XMAC) { if ((rs = npi_xmac_tx_config(handle, DISABLE, nxgep->mac.portnum, CFG_XMAC_TX)) != NPI_SUCCESS) goto fail; } else { if ((rs = npi_bmac_tx_config(handle, DISABLE, nxgep->mac.portnum, CFG_BMAC_TX)) != NPI_SUCCESS) goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_tx_mac_disable: port<%d>", nxgep->mac.portnum)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_tx_mac_disable: Failed to disable port<%d> TxMAC", nxgep->mac.portnum)); return (NXGE_ERROR | rs); } /* Enable RXMAC */ nxge_status_t nxge_rx_mac_enable(p_nxge_t nxgep) { npi_handle_t handle; uint8_t portn; npi_status_t rs = NPI_SUCCESS; nxge_status_t status = NXGE_OK; /* This is a service-domain-only activity. */ if (isLDOMguest(nxgep)) return (status); handle = nxgep->npi_handle; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_rx_mac_enable: port<%d>", portn)); if ((status = nxge_rx_mac_init(nxgep)) != NXGE_OK) goto fail; if (nxgep->mac.porttype == PORT_TYPE_XMAC) { if ((rs = npi_xmac_rx_config(handle, ENABLE, portn, CFG_XMAC_RX)) != NPI_SUCCESS) goto fail; } else { if ((rs = npi_bmac_rx_config(handle, ENABLE, portn, CFG_BMAC_RX)) != NPI_SUCCESS) goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_rx_mac_enable: port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxgep_rx_mac_enable: Failed to enable port<%d> RxMAC", portn)); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); else return (status); } /* Disable RXMAC */ nxge_status_t nxge_rx_mac_disable(p_nxge_t nxgep) { npi_handle_t handle; uint8_t portn; npi_status_t rs = NPI_SUCCESS; /* If we are a guest domain driver, don't bother. */ if (isLDOMguest(nxgep)) return (NXGE_OK); handle = nxgep->npi_handle; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_rx_mac_disable: port<%d>", portn)); if (nxgep->mac.porttype == PORT_TYPE_XMAC) { if ((rs = npi_xmac_rx_config(handle, DISABLE, portn, CFG_XMAC_RX)) != NPI_SUCCESS) goto fail; } else { if ((rs = npi_bmac_rx_config(handle, DISABLE, portn, CFG_BMAC_RX)) != NPI_SUCCESS) goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_rx_mac_disable: port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxgep_rx_mac_disable: Failed to disable port<%d> RxMAC", portn)); return (NXGE_ERROR | rs); } /* Reset TXMAC */ nxge_status_t nxge_tx_mac_reset(p_nxge_t nxgep) { npi_handle_t handle; uint8_t portn; npi_status_t rs = NPI_SUCCESS; handle = nxgep->npi_handle; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_tx_mac_reset: port<%d>", portn)); if (nxgep->mac.porttype == PORT_TYPE_XMAC) { if ((rs = npi_xmac_reset(handle, portn, XTX_MAC_RESET_ALL)) != NPI_SUCCESS) goto fail; } else { if ((rs = npi_bmac_reset(handle, portn, TX_MAC_RESET)) != NPI_SUCCESS) goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_tx_mac_reset: port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_tx_mac_reset: Failed to Reset TxMAC port<%d>", portn)); return (NXGE_ERROR | rs); } /* Reset RXMAC */ nxge_status_t nxge_rx_mac_reset(p_nxge_t nxgep) { npi_handle_t handle; uint8_t portn; npi_status_t rs = NPI_SUCCESS; handle = nxgep->npi_handle; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_rx_mac_reset: port<%d>", portn)); if (nxgep->mac.porttype == PORT_TYPE_XMAC) { if ((rs = npi_xmac_reset(handle, portn, XRX_MAC_RESET_ALL)) != NPI_SUCCESS) goto fail; } else { if ((rs = npi_bmac_reset(handle, portn, RX_MAC_RESET)) != NPI_SUCCESS) goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_rx_mac_reset: port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rx_mac_reset: Failed to Reset RxMAC port<%d>", portn)); return (NXGE_ERROR | rs); } /* 10G fiber link interrupt start routine */ static nxge_status_t nxge_10G_link_intr_start(p_nxge_t nxgep) { npi_status_t rs = NPI_SUCCESS; uint8_t portn = nxgep->mac.portnum; rs = npi_xmac_xpcs_link_intr_enable(nxgep->npi_handle, portn); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); else return (NXGE_OK); } /* 10G fiber link interrupt stop routine */ static nxge_status_t nxge_10G_link_intr_stop(p_nxge_t nxgep) { npi_status_t rs = NPI_SUCCESS; uint8_t portn = nxgep->mac.portnum; rs = npi_xmac_xpcs_link_intr_disable(nxgep->npi_handle, portn); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); else return (NXGE_OK); } /* 1G fiber link interrupt start routine */ static nxge_status_t nxge_1G_fiber_link_intr_start(p_nxge_t nxgep) { npi_status_t rs = NPI_SUCCESS; uint8_t portn = nxgep->mac.portnum; rs = npi_mac_pcs_link_intr_enable(nxgep->npi_handle, portn); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); else return (NXGE_OK); } /* 1G fiber link interrupt stop routine */ static nxge_status_t nxge_1G_fiber_link_intr_stop(p_nxge_t nxgep) { npi_status_t rs = NPI_SUCCESS; uint8_t portn = nxgep->mac.portnum; rs = npi_mac_pcs_link_intr_disable(nxgep->npi_handle, portn); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); else return (NXGE_OK); } /* 1G copper link interrupt start routine */ static nxge_status_t nxge_1G_copper_link_intr_start(p_nxge_t nxgep) { npi_status_t rs = NPI_SUCCESS; uint8_t portn = nxgep->mac.portnum; rs = npi_mac_mif_link_intr_enable(nxgep->npi_handle, portn, MII_STATUS, MII_STATUS_LINKUP); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); else return (NXGE_OK); } /* 1G copper link interrupt stop routine */ static nxge_status_t nxge_1G_copper_link_intr_stop(p_nxge_t nxgep) { npi_status_t rs = NPI_SUCCESS; uint8_t portn = nxgep->mac.portnum; rs = npi_mac_mif_link_intr_disable(nxgep->npi_handle, portn); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); else return (NXGE_OK); } /* Enable/Disable Link Status change interrupt */ nxge_status_t nxge_link_intr(p_nxge_t nxgep, link_intr_enable_t enable) { uint8_t portn; nxge_status_t status = NXGE_OK; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_link_intr: port<%d>", portn)); if (!nxgep->xcvr.link_intr_stop || !nxgep->xcvr.link_intr_start) return (NXGE_OK); if (enable == LINK_INTR_START) status = nxgep->xcvr.link_intr_start(nxgep); else if (enable == LINK_INTR_STOP) status = nxgep->xcvr.link_intr_stop(nxgep); if (status != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_link_intr: port<%d>", portn)); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_link_intr: Failed to set port<%d> mif intr mode", portn)); return (status); } /* Initialize 1G Fiber / Copper transceiver using Clause 22 */ nxge_status_t nxge_mii_xcvr_init(p_nxge_t nxgep) { p_nxge_param_t param_arr; p_nxge_stats_t statsp; uint8_t xcvr_portn; p_mii_regs_t mii_regs; mii_bmcr_t bmcr; mii_bmsr_t bmsr; mii_anar_t anar; mii_gcr_t gcr; mii_esr_t esr; mii_aux_ctl_t bcm5464r_aux; int status = NXGE_OK; uint_t delay; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mii_xcvr_init")); param_arr = nxgep->param_arr; statsp = nxgep->statsp; xcvr_portn = statsp->mac_stats.xcvr_portn; mii_regs = NULL; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_param_autoneg = 0x%02x", param_arr[param_autoneg].value)); /* * The mif phy mode may be connected to either a copper link * or fiber link. Read the mode control register to get the fiber * configuration if it is hard-wired to fiber link. */ (void) nxge_mii_get_link_mode(nxgep); if (nxgep->mac.portmode == PORT_1G_RGMII_FIBER) { return (nxge_mii_xcvr_fiber_init(nxgep)); } /* * Reset the transceiver. */ delay = 0; bmcr.value = 0; bmcr.bits.reset = 1; if ((status = nxge_mii_write(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)&mii_regs->bmcr, #else (uint8_t)(uint64_t)&mii_regs->bmcr, #endif bmcr.value)) != NXGE_OK) goto fail; do { drv_usecwait(500); if ((status = nxge_mii_read(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)&mii_regs->bmcr, #else (uint8_t)(uint64_t)&mii_regs->bmcr, #endif &bmcr.value)) != NXGE_OK) goto fail; delay++; } while ((bmcr.bits.reset) && (delay < 1000)); if (delay == 1000) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Xcvr reset failed.")); goto fail; } if ((status = nxge_mii_read(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->bmsr), #else (uint8_t)(uint64_t)(&mii_regs->bmsr), #endif &bmsr.value)) != NXGE_OK) goto fail; param_arr[param_autoneg].value &= bmsr.bits.auto_neg_able; param_arr[param_anar_100T4].value &= bmsr.bits.link_100T4; param_arr[param_anar_100fdx].value &= bmsr.bits.link_100fdx; param_arr[param_anar_100hdx].value = 0; param_arr[param_anar_10fdx].value &= bmsr.bits.link_10fdx; param_arr[param_anar_10hdx].value = 0; /* * Initialize the xcvr statistics. */ statsp->mac_stats.cap_autoneg = bmsr.bits.auto_neg_able; statsp->mac_stats.cap_100T4 = bmsr.bits.link_100T4; statsp->mac_stats.cap_100fdx = bmsr.bits.link_100fdx; statsp->mac_stats.cap_100hdx = 0; statsp->mac_stats.cap_10fdx = bmsr.bits.link_10fdx; statsp->mac_stats.cap_10hdx = 0; statsp->mac_stats.cap_asmpause = param_arr[param_anar_asmpause].value; statsp->mac_stats.cap_pause = param_arr[param_anar_pause].value; /* * Initialize the xcvr advertised capability statistics. */ statsp->mac_stats.adv_cap_autoneg = param_arr[param_autoneg].value; statsp->mac_stats.adv_cap_1000fdx = param_arr[param_anar_1000fdx].value; statsp->mac_stats.adv_cap_1000hdx = param_arr[param_anar_1000hdx].value; statsp->mac_stats.adv_cap_100T4 = param_arr[param_anar_100T4].value; statsp->mac_stats.adv_cap_100fdx = param_arr[param_anar_100fdx].value; statsp->mac_stats.adv_cap_100hdx = param_arr[param_anar_100hdx].value; statsp->mac_stats.adv_cap_10fdx = param_arr[param_anar_10fdx].value; statsp->mac_stats.adv_cap_10hdx = param_arr[param_anar_10hdx].value; statsp->mac_stats.adv_cap_asmpause = param_arr[param_anar_asmpause].value; statsp->mac_stats.adv_cap_pause = param_arr[param_anar_pause].value; /* * Check for extended status just in case we're * running a Gigibit phy. */ if (bmsr.bits.extend_status) { if ((status = nxge_mii_read(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->esr), #else (uint8_t)(uint64_t)(&mii_regs->esr), #endif &esr.value)) != NXGE_OK) goto fail; param_arr[param_anar_1000fdx].value &= esr.bits.link_1000fdx; param_arr[param_anar_1000hdx].value = 0; statsp->mac_stats.cap_1000fdx = (esr.bits.link_1000Xfdx || esr.bits.link_1000fdx); statsp->mac_stats.cap_1000hdx = 0; } else { param_arr[param_anar_1000fdx].value = 0; param_arr[param_anar_1000hdx].value = 0; } /* * Initialize 1G Statistics once the capability is established. */ statsp->mac_stats.adv_cap_1000fdx = param_arr[param_anar_1000fdx].value; statsp->mac_stats.adv_cap_1000hdx = param_arr[param_anar_1000hdx].value; /* * Initialize the link statistics. */ statsp->mac_stats.link_T4 = 0; statsp->mac_stats.link_asmpause = 0; statsp->mac_stats.link_pause = 0; statsp->mac_stats.link_speed = 0; statsp->mac_stats.link_duplex = 0; statsp->mac_stats.link_up = 0; /* * Switch off Auto-negotiation, 100M and full duplex. */ bmcr.value = 0; if ((status = nxge_mii_write(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->bmcr), #else (uint8_t)(uint64_t)(&mii_regs->bmcr), #endif bmcr.value)) != NXGE_OK) goto fail; if ((statsp->port_stats.lb_mode == nxge_lb_phy) || (statsp->port_stats.lb_mode == nxge_lb_phy1000)) { bmcr.bits.loopback = 1; bmcr.bits.enable_autoneg = 0; if (statsp->port_stats.lb_mode == nxge_lb_phy1000) bmcr.bits.speed_1000_sel = 1; bmcr.bits.duplex_mode = 1; param_arr[param_autoneg].value = 0; } else { bmcr.bits.loopback = 0; } if ((statsp->port_stats.lb_mode == nxge_lb_ext1000) || (statsp->port_stats.lb_mode == nxge_lb_ext100) || (statsp->port_stats.lb_mode == nxge_lb_ext10)) { param_arr[param_autoneg].value = 0; bcm5464r_aux.value = 0; bcm5464r_aux.bits.ext_lb = 1; bcm5464r_aux.bits.write_1 = 1; if ((status = nxge_mii_write(nxgep, xcvr_portn, BCM5464R_AUX_CTL, bcm5464r_aux.value)) != NXGE_OK) goto fail; } /* If auto-negotiation is desired */ if (param_arr[param_autoneg].value) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Restarting Auto-negotiation.")); /* * Setup our Auto-negotiation advertisement register. */ anar.value = 0; anar.bits.selector = 1; anar.bits.cap_100T4 = param_arr[param_anar_100T4].value; anar.bits.cap_100fdx = param_arr[param_anar_100fdx].value; anar.bits.cap_100hdx = param_arr[param_anar_100hdx].value; anar.bits.cap_10fdx = param_arr[param_anar_10fdx].value; anar.bits.cap_10hdx = param_arr[param_anar_10hdx].value; anar.bits.cap_asmpause = 0; anar.bits.cap_pause = 0; if (param_arr[param_anar_1000fdx].value || param_arr[param_anar_100fdx].value || param_arr[param_anar_10fdx].value) { anar.bits.cap_asmpause = statsp->mac_stats.cap_asmpause; anar.bits.cap_pause = statsp->mac_stats.cap_pause; } /* Write to the auto-negotiation advertisement register */ if ((status = nxge_mii_write(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->anar), #else (uint8_t)(uint64_t)(&mii_regs->anar), #endif anar.value)) != NXGE_OK) goto fail; if (bmsr.bits.extend_status) { gcr.value = 0; gcr.bits.ms_mode_en = param_arr[param_master_cfg_enable].value; gcr.bits.master = param_arr[param_master_cfg_value].value; gcr.bits.link_1000fdx = param_arr[param_anar_1000fdx].value; gcr.bits.link_1000hdx = param_arr[param_anar_1000hdx].value; if ((status = nxge_mii_write(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->gcr), #else (uint8_t)(uint64_t)(&mii_regs->gcr), #endif gcr.value)) != NXGE_OK) goto fail; } bmcr.bits.enable_autoneg = 1; bmcr.bits.restart_autoneg = 1; } else { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Going into forced mode.")); bmcr.bits.speed_1000_sel = param_arr[param_anar_1000fdx].value | param_arr[param_anar_1000hdx].value; bmcr.bits.speed_sel = (~bmcr.bits.speed_1000_sel) & (param_arr[param_anar_100fdx].value | param_arr[param_anar_100hdx].value); /* Force to 1G */ if (bmcr.bits.speed_1000_sel) { statsp->mac_stats.link_speed = 1000; gcr.value = 0; gcr.bits.ms_mode_en = param_arr[param_master_cfg_enable].value; gcr.bits.master = param_arr[param_master_cfg_value].value; if ((status = nxge_mii_write(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->gcr), #else (uint8_t)(uint64_t)(&mii_regs->gcr), #endif gcr.value)) != NXGE_OK) goto fail; if (param_arr[param_anar_1000fdx].value) { bmcr.bits.duplex_mode = 1; statsp->mac_stats.link_duplex = 2; } else statsp->mac_stats.link_duplex = 1; /* Force to 100M */ } else if (bmcr.bits.speed_sel) { statsp->mac_stats.link_speed = 100; if (param_arr[param_anar_100fdx].value) { bmcr.bits.duplex_mode = 1; statsp->mac_stats.link_duplex = 2; } else statsp->mac_stats.link_duplex = 1; /* Force to 10M */ } else { statsp->mac_stats.link_speed = 10; if (param_arr[param_anar_10fdx].value) { bmcr.bits.duplex_mode = 1; statsp->mac_stats.link_duplex = 2; } else statsp->mac_stats.link_duplex = 1; } if (statsp->mac_stats.link_duplex != 1) { statsp->mac_stats.link_asmpause = statsp->mac_stats.cap_asmpause; statsp->mac_stats.link_pause = statsp->mac_stats.cap_pause; } if ((statsp->port_stats.lb_mode == nxge_lb_ext1000) || (statsp->port_stats.lb_mode == nxge_lb_ext100) || (statsp->port_stats.lb_mode == nxge_lb_ext10)) { if (statsp->port_stats.lb_mode == nxge_lb_ext1000) { /* BCM5464R 1000mbps external loopback mode */ gcr.value = 0; gcr.bits.ms_mode_en = 1; gcr.bits.master = 1; if ((status = nxge_mii_write(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->gcr), #else (uint8_t)(uint64_t)(&mii_regs->gcr), #endif gcr.value)) != NXGE_OK) goto fail; bmcr.value = 0; bmcr.bits.speed_1000_sel = 1; statsp->mac_stats.link_speed = 1000; } else if (statsp->port_stats.lb_mode == nxge_lb_ext100) { /* BCM5464R 100mbps external loopback mode */ bmcr.value = 0; bmcr.bits.speed_sel = 1; bmcr.bits.duplex_mode = 1; statsp->mac_stats.link_speed = 100; } else if (statsp->port_stats.lb_mode == nxge_lb_ext10) { /* BCM5464R 10mbps external loopback mode */ bmcr.value = 0; bmcr.bits.duplex_mode = 1; statsp->mac_stats.link_speed = 10; } } } if ((status = nxge_mii_write(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->bmcr), #else (uint8_t)(uint64_t)(&mii_regs->bmcr), #endif bmcr.value)) != NXGE_OK) goto fail; if ((status = nxge_mii_read(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->bmcr), #else (uint8_t)(uint64_t)(&mii_regs->bmcr), #endif &bmcr.value)) != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "bmcr = 0x%04X", bmcr.value)); /* * Initialize the xcvr status kept in the context structure. */ nxgep->soft_bmsr.value = 0; if ((status = nxge_mii_read(nxgep, xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->bmsr), #else (uint8_t)(uint64_t)(&mii_regs->bmsr), #endif &nxgep->bmsr.value)) != NXGE_OK) goto fail; statsp->mac_stats.xcvr_inits++; nxgep->bmsr.value = 0; fail: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_mii_xcvr_init status 0x%x", status)); return (status); } nxge_status_t nxge_mii_xcvr_fiber_init(p_nxge_t nxgep) { p_nxge_param_t param_arr; p_nxge_stats_t statsp; uint8_t xcvr_portn; p_mii_regs_t mii_regs; mii_bmcr_t bmcr; mii_bmsr_t bmsr; mii_gcr_t gcr; mii_esr_t esr; mii_aux_ctl_t bcm5464r_aux; int status = NXGE_OK; uint_t delay; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mii_xcvr_fiber_init")); param_arr = nxgep->param_arr; statsp = nxgep->statsp; xcvr_portn = statsp->mac_stats.xcvr_portn; mii_regs = NULL; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_mii_xcvr_fiber_init: " "nxge_param_autoneg = 0x%02x", param_arr[param_autoneg].value)); /* * Reset the transceiver. */ delay = 0; bmcr.value = 0; bmcr.bits.reset = 1; #if defined(__i386) if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmcr), bmcr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmcr), bmcr.value)) != NXGE_OK) goto fail; #endif do { drv_usecwait(500); #if defined(__i386) if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmcr), &bmcr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmcr), &bmcr.value)) != NXGE_OK) goto fail; #endif delay++; } while ((bmcr.bits.reset) && (delay < 1000)); if (delay == 1000) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Xcvr reset failed.")); goto fail; } #if defined(__i386) if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmsr), &bmsr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmsr), &bmsr.value)) != NXGE_OK) goto fail; #endif param_arr[param_autoneg].value &= bmsr.bits.auto_neg_able; param_arr[param_anar_100T4].value = 0; param_arr[param_anar_100fdx].value = 0; param_arr[param_anar_100hdx].value = 0; param_arr[param_anar_10fdx].value = 0; param_arr[param_anar_10hdx].value = 0; /* * Initialize the xcvr statistics. */ statsp->mac_stats.cap_autoneg = bmsr.bits.auto_neg_able; statsp->mac_stats.cap_100T4 = 0; statsp->mac_stats.cap_100fdx = 0; statsp->mac_stats.cap_100hdx = 0; statsp->mac_stats.cap_10fdx = 0; statsp->mac_stats.cap_10hdx = 0; statsp->mac_stats.cap_asmpause = param_arr[param_anar_asmpause].value; statsp->mac_stats.cap_pause = param_arr[param_anar_pause].value; /* * Initialize the xcvr advertised capability statistics. */ statsp->mac_stats.adv_cap_autoneg = param_arr[param_autoneg].value; statsp->mac_stats.adv_cap_1000fdx = param_arr[param_anar_1000fdx].value; statsp->mac_stats.adv_cap_1000hdx = param_arr[param_anar_1000hdx].value; statsp->mac_stats.adv_cap_100T4 = param_arr[param_anar_100T4].value; statsp->mac_stats.adv_cap_100fdx = param_arr[param_anar_100fdx].value; statsp->mac_stats.adv_cap_100hdx = param_arr[param_anar_100hdx].value; statsp->mac_stats.adv_cap_10fdx = param_arr[param_anar_10fdx].value; statsp->mac_stats.adv_cap_10hdx = param_arr[param_anar_10hdx].value; statsp->mac_stats.adv_cap_asmpause = param_arr[param_anar_asmpause].value; statsp->mac_stats.adv_cap_pause = param_arr[param_anar_pause].value; /* * Check for extended status just in case we're * running a Gigibit phy. */ if (bmsr.bits.extend_status) { #if defined(__i386) if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->esr), &esr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->esr), &esr.value)) != NXGE_OK) goto fail; #endif param_arr[param_anar_1000fdx].value &= esr.bits.link_1000fdx; param_arr[param_anar_1000hdx].value = 0; statsp->mac_stats.cap_1000fdx = (esr.bits.link_1000Xfdx || esr.bits.link_1000fdx); statsp->mac_stats.cap_1000hdx = 0; } else { param_arr[param_anar_1000fdx].value = 0; param_arr[param_anar_1000hdx].value = 0; } /* * Initialize 1G Statistics once the capability is established. */ statsp->mac_stats.adv_cap_1000fdx = param_arr[param_anar_1000fdx].value; statsp->mac_stats.adv_cap_1000hdx = param_arr[param_anar_1000hdx].value; /* * Initialize the link statistics. */ statsp->mac_stats.link_T4 = 0; statsp->mac_stats.link_asmpause = 0; statsp->mac_stats.link_pause = 0; statsp->mac_stats.link_speed = 0; statsp->mac_stats.link_duplex = 0; statsp->mac_stats.link_up = 0; /* * Switch off Auto-negotiation, 100M and full duplex. */ bmcr.value = 0; #if defined(__i386) if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmcr), bmcr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmcr), bmcr.value)) != NXGE_OK) goto fail; #endif if ((statsp->port_stats.lb_mode == nxge_lb_phy) || (statsp->port_stats.lb_mode == nxge_lb_phy1000)) { bmcr.bits.loopback = 1; bmcr.bits.enable_autoneg = 0; if (statsp->port_stats.lb_mode == nxge_lb_phy1000) bmcr.bits.speed_1000_sel = 1; bmcr.bits.duplex_mode = 1; param_arr[param_autoneg].value = 0; } else { bmcr.bits.loopback = 0; } if (statsp->port_stats.lb_mode == nxge_lb_ext1000) { param_arr[param_autoneg].value = 0; bcm5464r_aux.value = 0; bcm5464r_aux.bits.ext_lb = 1; bcm5464r_aux.bits.write_1 = 1; if ((status = nxge_mii_write(nxgep, xcvr_portn, BCM5464R_AUX_CTL, bcm5464r_aux.value)) != NXGE_OK) goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Going into forced mode.")); bmcr.bits.speed_1000_sel = 1; bmcr.bits.speed_sel = 0; bmcr.bits.duplex_mode = 1; statsp->mac_stats.link_speed = 1000; statsp->mac_stats.link_duplex = 2; if ((statsp->port_stats.lb_mode == nxge_lb_ext1000)) { /* BCM5464R 1000mbps external loopback mode */ gcr.value = 0; gcr.bits.ms_mode_en = 1; gcr.bits.master = 1; #if defined(__i386) if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->gcr), gcr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->gcr), gcr.value)) != NXGE_OK) goto fail; #endif bmcr.value = 0; bmcr.bits.speed_1000_sel = 1; statsp->mac_stats.link_speed = 1000; } #if defined(__i386) if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmcr), bmcr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmcr), bmcr.value)) != NXGE_OK) goto fail; #endif NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_mii_xcvr_fiber_init: value wrote bmcr = 0x%x", bmcr.value)); #if defined(__i386) if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmcr), &bmcr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmcr), &bmcr.value)) != NXGE_OK) goto fail; #endif NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_mii_xcvr_fiber_init: read bmcr = 0x%04X", bmcr.value)); /* * Initialize the xcvr status kept in the context structure. */ nxgep->soft_bmsr.value = 0; #if defined(__i386) if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmsr), &nxgep->bmsr.value)) != NXGE_OK) goto fail; #else if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmsr), &nxgep->bmsr.value)) != NXGE_OK) goto fail; #endif statsp->mac_stats.xcvr_inits++; nxgep->bmsr.value = 0; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_mii_xcvr_fiber_init status 0x%x", status)); return (status); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_mii_xcvr_fiber_init status 0x%x", status)); return (status); } /* Read from a MII compliant register */ nxge_status_t nxge_mii_read(p_nxge_t nxgep, uint8_t xcvr_portn, uint8_t xcvr_reg, uint16_t *value) { npi_status_t rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, MIF_CTL, "==> nxge_mii_read: xcvr_port<%d>" "xcvr_reg<%d>", xcvr_portn, xcvr_reg)); MUTEX_ENTER(&nxgep->nxge_hw_p->nxge_mdio_lock); if ((nxgep->mac.portmode == PORT_1G_COPPER) || (nxgep->mac.portmode == PORT_1G_RGMII_FIBER)) { if ((rs = npi_mac_mif_mii_read(nxgep->npi_handle, xcvr_portn, xcvr_reg, value)) != NPI_SUCCESS) goto fail; } else if ((nxgep->mac.portmode == PORT_1G_FIBER) || (nxgep->mac.portmode == PORT_1G_SERDES)) { if ((rs = npi_mac_pcs_mii_read(nxgep->npi_handle, xcvr_portn, xcvr_reg, value)) != NPI_SUCCESS) goto fail; } else goto fail; MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_DEBUG_MSG((nxgep, MIF_CTL, "<== nxge_mii_read: xcvr_port<%d>" "xcvr_reg<%d> value=0x%x", xcvr_portn, xcvr_reg, *value)); return (NXGE_OK); fail: MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mii_read: Failed to read mii on xcvr %d", xcvr_portn)); return (NXGE_ERROR | rs); } /* Write to a MII compliant Register */ nxge_status_t nxge_mii_write(p_nxge_t nxgep, uint8_t xcvr_portn, uint8_t xcvr_reg, uint16_t value) { npi_status_t rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, MIF_CTL, "==> nxge_mii_write: xcvr_port<%d>" "xcvr_reg<%d> value=0x%x", xcvr_portn, xcvr_reg, value)); MUTEX_ENTER(&nxgep->nxge_hw_p->nxge_mdio_lock); if ((nxgep->mac.portmode == PORT_1G_COPPER) || (nxgep->mac.portmode == PORT_1G_RGMII_FIBER)) { if ((rs = npi_mac_mif_mii_write(nxgep->npi_handle, xcvr_portn, xcvr_reg, value)) != NPI_SUCCESS) goto fail; } else if ((nxgep->mac.portmode == PORT_1G_FIBER) || (nxgep->mac.portmode == PORT_1G_SERDES)) { if ((rs = npi_mac_pcs_mii_write(nxgep->npi_handle, xcvr_portn, xcvr_reg, value)) != NPI_SUCCESS) goto fail; } else goto fail; MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_DEBUG_MSG((nxgep, MIF_CTL, "<== nxge_mii_write: xcvr_port<%d>" "xcvr_reg<%d>", xcvr_portn, xcvr_reg)); return (NXGE_OK); fail: MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mii_write: Failed to write mii on xcvr %d", xcvr_portn)); return (NXGE_ERROR | rs); } /* * Perform write to Clause45 serdes / transceiver device * Arguments: * xcvr_portn: The IEEE 802.3 Clause45 PHYAD, it is the same as port * number if nxge_mdio_write is used for accessing the * internal LSIL serdes. Otherwise PHYAD is different * for different platforms. * device: With each PHYAD, the driver can use MDIO to control * multiple devices inside the PHY, here "device" is an * MMD (MDIO managable device). * xcvr_reg: Each device has multiple registers. xcvr_reg specifies * the register which the driver will write value to. * value: The register value will be filled in. */ nxge_status_t nxge_mdio_read(p_nxge_t nxgep, uint8_t xcvr_portn, uint8_t device, uint16_t xcvr_reg, uint16_t *value) { npi_status_t rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, MIF_CTL, "==> nxge_mdio_read: xcvr_port<%d>", xcvr_portn)); MUTEX_ENTER(&nxgep->nxge_hw_p->nxge_mdio_lock); if ((rs = npi_mac_mif_mdio_read(nxgep->npi_handle, xcvr_portn, device, xcvr_reg, value)) != NPI_SUCCESS) goto fail; MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_DEBUG_MSG((nxgep, MIF_CTL, "<== nxge_mdio_read: xcvr_port<%d>", xcvr_portn)); return (NXGE_OK); fail: MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mdio_read: Failed to read mdio on xcvr %d", xcvr_portn)); return (NXGE_ERROR | rs); } /* Perform write to Clause45 serdes / transceiver device */ nxge_status_t nxge_mdio_write(p_nxge_t nxgep, uint8_t xcvr_portn, uint8_t device, uint16_t xcvr_reg, uint16_t value) { npi_status_t rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, MIF_CTL, "==> nxge_mdio_write: xcvr_port<%d>", xcvr_portn)); MUTEX_ENTER(&nxgep->nxge_hw_p->nxge_mdio_lock); if ((rs = npi_mac_mif_mdio_write(nxgep->npi_handle, xcvr_portn, device, xcvr_reg, value)) != NPI_SUCCESS) goto fail; MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_DEBUG_MSG((nxgep, MIF_CTL, "<== nxge_mdio_write: xcvr_port<%d>", xcvr_portn)); return (NXGE_OK); fail: MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mdio_write: Failed to write mdio on xcvr %d", xcvr_portn)); return (NXGE_ERROR | rs); } /* Check MII to see if there is any link status change */ nxge_status_t nxge_mii_check(p_nxge_t nxgep, mii_bmsr_t bmsr, mii_bmsr_t bmsr_ints, nxge_link_state_t *link_up) { p_nxge_param_t param_arr; p_nxge_stats_t statsp; p_mii_regs_t mii_regs; p_mii_bmsr_t soft_bmsr; mii_anar_t anar; mii_anlpar_t anlpar; mii_anar_t an_common; mii_aner_t aner; mii_gsr_t gsr; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mii_check")); mii_regs = NULL; param_arr = nxgep->param_arr; statsp = nxgep->statsp; soft_bmsr = &nxgep->soft_bmsr; *link_up = LINK_NO_CHANGE; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mii_check bmsr 0x%x bmsr_int 0x%x", bmsr.value, bmsr_ints.value)); if (bmsr_ints.bits.link_status) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mii_check (link up) bmsr 0x%x bmsr_int 0x%x", bmsr.value, bmsr_ints.value)); if (bmsr.bits.link_status) { soft_bmsr->bits.link_status = 1; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mii_check (link up) soft bmsr 0x%x bmsr_int " "0x%x", bmsr.value, bmsr_ints.value)); } else { statsp->mac_stats.link_up = 0; soft_bmsr->bits.link_status = 0; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Link down cable problem")); *link_up = LINK_IS_DOWN; } } if (nxgep->mac.portmode == PORT_1G_COPPER && param_arr[param_autoneg].value) { if (bmsr_ints.bits.auto_neg_complete) { if (bmsr.bits.auto_neg_complete) soft_bmsr->bits.auto_neg_complete = 1; else soft_bmsr->bits.auto_neg_complete = 0; } if (soft_bmsr->bits.link_status == 0) { statsp->mac_stats.link_T4 = 0; statsp->mac_stats.link_speed = 0; statsp->mac_stats.link_duplex = 0; statsp->mac_stats.link_asmpause = 0; statsp->mac_stats.link_pause = 0; statsp->mac_stats.lp_cap_autoneg = 0; statsp->mac_stats.lp_cap_100T4 = 0; statsp->mac_stats.lp_cap_1000fdx = 0; statsp->mac_stats.lp_cap_1000hdx = 0; statsp->mac_stats.lp_cap_100fdx = 0; statsp->mac_stats.lp_cap_100hdx = 0; statsp->mac_stats.lp_cap_10fdx = 0; statsp->mac_stats.lp_cap_10hdx = 0; statsp->mac_stats.lp_cap_10gfdx = 0; statsp->mac_stats.lp_cap_10ghdx = 0; statsp->mac_stats.lp_cap_asmpause = 0; statsp->mac_stats.lp_cap_pause = 0; } } else soft_bmsr->bits.auto_neg_complete = 1; if ((bmsr_ints.bits.link_status || bmsr_ints.bits.auto_neg_complete) && soft_bmsr->bits.link_status && soft_bmsr->bits.auto_neg_complete) { statsp->mac_stats.link_up = 1; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mii_check " "(auto negotiation complete or link up) " "soft bmsr 0x%x bmsr_int 0x%x", bmsr.value, bmsr_ints.value)); if (nxgep->mac.portmode == PORT_1G_COPPER && param_arr[param_autoneg].value) { if ((status = nxge_mii_read(nxgep, statsp->mac_stats.xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->anar), #else (uint8_t)(uint64_t)(&mii_regs->anar), #endif &anar.value)) != NXGE_OK) goto fail; if ((status = nxge_mii_read(nxgep, statsp->mac_stats.xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->anlpar), #else (uint8_t)(uint64_t)(&mii_regs->anlpar), #endif &anlpar.value)) != NXGE_OK) goto fail; if ((status = nxge_mii_read(nxgep, statsp->mac_stats.xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->aner), #else (uint8_t)(uint64_t)(&mii_regs->aner), #endif &aner.value)) != NXGE_OK) goto fail; statsp->mac_stats.lp_cap_autoneg = aner.bits.lp_an_able; statsp->mac_stats.lp_cap_100T4 = anlpar.bits.cap_100T4; statsp->mac_stats.lp_cap_100fdx = anlpar.bits.cap_100fdx; statsp->mac_stats.lp_cap_100hdx = anlpar.bits.cap_100hdx; statsp->mac_stats.lp_cap_10fdx = anlpar.bits.cap_10fdx; statsp->mac_stats.lp_cap_10hdx = anlpar.bits.cap_10hdx; statsp->mac_stats.lp_cap_asmpause = anlpar.bits.cap_asmpause; statsp->mac_stats.lp_cap_pause = anlpar.bits.cap_pause; an_common.value = anar.value & anlpar.value; if (param_arr[param_anar_1000fdx].value || param_arr[param_anar_1000hdx].value) { if ((status = nxge_mii_read(nxgep, statsp->mac_stats.xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->gsr), #else (uint8_t)(uint64_t)(&mii_regs->gsr), #endif &gsr.value)) != NXGE_OK) goto fail; statsp->mac_stats.lp_cap_1000fdx = gsr.bits.link_1000fdx; statsp->mac_stats.lp_cap_1000hdx = gsr.bits.link_1000hdx; if (param_arr[param_anar_1000fdx].value && gsr.bits.link_1000fdx) { statsp->mac_stats.link_speed = 1000; statsp->mac_stats.link_duplex = 2; } else if ( param_arr[param_anar_1000hdx].value && gsr.bits.link_1000hdx) { statsp->mac_stats.link_speed = 1000; statsp->mac_stats.link_duplex = 1; } } if ((an_common.value != 0) && !(statsp->mac_stats.link_speed)) { if (an_common.bits.cap_100T4) { statsp->mac_stats.link_T4 = 1; statsp->mac_stats.link_speed = 100; statsp->mac_stats.link_duplex = 1; } else if (an_common.bits.cap_100fdx) { statsp->mac_stats.link_speed = 100; statsp->mac_stats.link_duplex = 2; } else if (an_common.bits.cap_100hdx) { statsp->mac_stats.link_speed = 100; statsp->mac_stats.link_duplex = 1; } else if (an_common.bits.cap_10fdx) { statsp->mac_stats.link_speed = 10; statsp->mac_stats.link_duplex = 2; } else if (an_common.bits.cap_10hdx) { statsp->mac_stats.link_speed = 10; statsp->mac_stats.link_duplex = 1; } else { goto fail; } } if (statsp->mac_stats.link_duplex != 1) { int link_pause; int cp, lcp; statsp->mac_stats.link_asmpause = an_common.bits.cap_asmpause; cp = statsp->mac_stats.cap_pause; lcp = statsp->mac_stats.lp_cap_pause; if (statsp->mac_stats.link_asmpause) { if ((cp == 0) && (lcp == 1)) { link_pause = 0; } else { link_pause = 1; } } else { link_pause = an_common.bits.cap_pause; } statsp->mac_stats.link_pause = link_pause; } } else if (nxgep->mac.portmode == PORT_1G_RGMII_FIBER) { statsp->mac_stats.link_speed = 1000; statsp->mac_stats.link_duplex = 2; } *link_up = LINK_IS_UP; } if (nxgep->link_notify) { *link_up = ((statsp->mac_stats.link_up) ? LINK_IS_UP : LINK_IS_DOWN); nxgep->link_notify = B_FALSE; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_mii_check")); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mii_check: Unable to check MII")); return (status); } /* * Check PCS to see if there is any link status change. * This function is called by PORT_1G_SERDES only. */ void nxge_pcs_check(p_nxge_t nxgep, uint8_t portn, nxge_link_state_t *link_up) { p_nxge_stats_t statsp; boolean_t linkup; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_pcs_check")); statsp = nxgep->statsp; *link_up = LINK_NO_CHANGE; (void) npi_mac_get_link_status(nxgep->npi_handle, portn, &linkup); if (linkup) { if (nxgep->link_notify || nxgep->statsp->mac_stats.link_up == 0) { statsp->mac_stats.link_up = 1; statsp->mac_stats.link_speed = 1000; statsp->mac_stats.link_duplex = 2; *link_up = LINK_IS_UP; nxgep->link_notify = B_FALSE; } } else { if (nxgep->link_notify || nxgep->statsp->mac_stats.link_up == 1) { statsp->mac_stats.link_up = 0; statsp->mac_stats.link_speed = 0; statsp->mac_stats.link_duplex = 0; *link_up = LINK_IS_DOWN; nxgep->link_notify = B_FALSE; } } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_pcs_check")); } /* Add a multicast address entry into the HW hash table */ nxge_status_t nxge_add_mcast_addr(p_nxge_t nxgep, struct ether_addr *addrp) { uint32_t mchash; p_hash_filter_t hash_filter; uint16_t hash_bit; boolean_t rx_init = B_FALSE; uint_t j; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_add_mcast_addr")); RW_ENTER_WRITER(&nxgep->filter_lock); mchash = crc32_mchash(addrp); if (nxgep->hash_filter == NULL) { NXGE_DEBUG_MSG((NULL, STR_CTL, "Allocating hash filter storage.")); nxgep->hash_filter = KMEM_ZALLOC(sizeof (hash_filter_t), KM_SLEEP); } hash_filter = nxgep->hash_filter; j = mchash / HASH_REG_WIDTH; hash_bit = (1 << (mchash % HASH_REG_WIDTH)); hash_filter->hash_filter_regs[j] |= hash_bit; hash_filter->hash_bit_ref_cnt[mchash]++; if (hash_filter->hash_bit_ref_cnt[mchash] == 1) { hash_filter->hash_ref_cnt++; rx_init = B_TRUE; } if (rx_init) { if ((status = nxge_rx_mac_disable(nxgep)) != NXGE_OK) goto fail; if ((status = nxge_rx_mac_enable(nxgep)) != NXGE_OK) goto fail; } RW_EXIT(&nxgep->filter_lock); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_add_mcast_addr")); return (NXGE_OK); fail: RW_EXIT(&nxgep->filter_lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_add_mcast_addr: " "Unable to add multicast address")); return (status); } /* Remove a multicast address entry from the HW hash table */ nxge_status_t nxge_del_mcast_addr(p_nxge_t nxgep, struct ether_addr *addrp) { uint32_t mchash; p_hash_filter_t hash_filter; uint16_t hash_bit; boolean_t rx_init = B_FALSE; uint_t j; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_del_mcast_addr")); RW_ENTER_WRITER(&nxgep->filter_lock); mchash = crc32_mchash(addrp); if (nxgep->hash_filter == NULL) { NXGE_DEBUG_MSG((NULL, STR_CTL, "Hash filter already de_allocated.")); RW_EXIT(&nxgep->filter_lock); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_del_mcast_addr")); return (NXGE_OK); } hash_filter = nxgep->hash_filter; hash_filter->hash_bit_ref_cnt[mchash]--; if (hash_filter->hash_bit_ref_cnt[mchash] == 0) { j = mchash / HASH_REG_WIDTH; hash_bit = (1 << (mchash % HASH_REG_WIDTH)); hash_filter->hash_filter_regs[j] &= ~hash_bit; hash_filter->hash_ref_cnt--; rx_init = B_TRUE; } if (hash_filter->hash_ref_cnt == 0) { NXGE_DEBUG_MSG((NULL, STR_CTL, "De-allocating hash filter storage.")); KMEM_FREE(hash_filter, sizeof (hash_filter_t)); nxgep->hash_filter = NULL; } if (rx_init) { if ((status = nxge_rx_mac_disable(nxgep)) != NXGE_OK) goto fail; if ((status = nxge_rx_mac_enable(nxgep)) != NXGE_OK) goto fail; } RW_EXIT(&nxgep->filter_lock); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_del_mcast_addr")); return (NXGE_OK); fail: RW_EXIT(&nxgep->filter_lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_del_mcast_addr: " "Unable to remove multicast address")); return (status); } /* Set MAC address into MAC address HW registers */ nxge_status_t nxge_set_mac_addr(p_nxge_t nxgep, struct ether_addr *addrp) { nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_set_mac_addr")); MUTEX_ENTER(&nxgep->ouraddr_lock); /* * Exit if the address is same as ouraddr or multicast or broadcast */ if (((addrp->ether_addr_octet[0] & 01) == 1) || (ether_cmp(addrp, ðerbroadcastaddr) == 0) || (ether_cmp(addrp, &nxgep->ouraddr) == 0)) { goto nxge_set_mac_addr_exit; } nxgep->ouraddr = *addrp; /* * Set new interface local address and re-init device. * This is destructive to any other streams attached * to this device. */ RW_ENTER_WRITER(&nxgep->filter_lock); if ((status = nxge_rx_mac_disable(nxgep)) != NXGE_OK) goto fail; if ((status = nxge_rx_mac_enable(nxgep)) != NXGE_OK) goto fail; RW_EXIT(&nxgep->filter_lock); MUTEX_EXIT(&nxgep->ouraddr_lock); goto nxge_set_mac_addr_end; nxge_set_mac_addr_exit: MUTEX_EXIT(&nxgep->ouraddr_lock); nxge_set_mac_addr_end: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_set_mac_addr")); return (NXGE_OK); fail: MUTEX_EXIT(&nxgep->ouraddr_lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_set_mac_addr: " "Unable to set mac address")); return (status); } static check_link_state_t nxge_check_link_stop(nxge_t *nxge) { /* If the poll has been cancelled, return STOP. */ MUTEX_ENTER(&nxge->poll_lock); if (nxge->suspended || nxge->poll_state == LINK_MONITOR_STOPPING) { nxge->poll_state = LINK_MONITOR_STOP; nxge->nxge_link_poll_timerid = 0; cv_broadcast(&nxge->poll_cv); MUTEX_EXIT(&nxge->poll_lock); NXGE_DEBUG_MSG((nxge, MAC_CTL, "nxge_check_%s_link(port<%d>) stopped.", nxge->mac.portmode == PORT_10G_FIBER ? "10g" : "mii", nxge->mac.portnum)); return (CHECK_LINK_STOP); } MUTEX_EXIT(&nxge->poll_lock); return (CHECK_LINK_RESCHEDULE); } /* * Check status of MII (MIF or PCS) link. * This function is called once per second, that is because this function * calls nxge_link_monitor with LINK_MONITOR_START, which starts a timer to * call this function recursively. */ static nxge_status_t nxge_check_mii_link(p_nxge_t nxgep) { mii_bmsr_t bmsr_ints, bmsr_data; mii_anlpar_t anlpar; mii_gsr_t gsr; p_mii_regs_t mii_regs; nxge_status_t status = NXGE_OK; uint8_t portn; nxge_link_state_t link_up; if (nxgep->nxge_magic != NXGE_MAGIC) return (NXGE_ERROR); if (nxge_check_link_stop(nxgep) == CHECK_LINK_STOP) return (NXGE_OK); portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_check_mii_link port<%d>", portn)); mii_regs = NULL; RW_ENTER_WRITER(&nxgep->filter_lock); if (nxgep->statsp->port_stats.lb_mode > nxge_lb_ext10) goto nxge_check_mii_link_exit; switch (nxgep->mac.portmode) { default: bmsr_data.value = 0; if ((status = nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->bmsr), #else (uint8_t)(uint64_t)(&mii_regs->bmsr), #endif &bmsr_data.value)) != NXGE_OK) { goto fail; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_check_mii_link port<0x%x> " "RIGHT AFTER READ bmsr_data 0x%x (nxgep->bmsr 0x%x ", portn, bmsr_data.value, nxgep->bmsr.value)); if (nxgep->param_arr[param_autoneg].value) { if ((status = nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->gsr), #else (uint8_t)(uint64_t)(&mii_regs->gsr), #endif &gsr.value)) != NXGE_OK) goto fail; if ((status = nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, #if defined(__i386) (uint8_t)(uint32_t)(&mii_regs->anlpar), #else (uint8_t)(uint64_t)(&mii_regs->anlpar), #endif &anlpar.value)) != NXGE_OK) goto fail; if (nxgep->mac.portmode != PORT_1G_RGMII_FIBER) { if (nxgep->statsp->mac_stats.link_up && ((nxgep->statsp->mac_stats.lp_cap_1000fdx ^ gsr.bits.link_1000fdx) || (nxgep->statsp->mac_stats.lp_cap_1000hdx ^ gsr.bits.link_1000hdx) || (nxgep->statsp->mac_stats.lp_cap_100T4 ^ anlpar.bits.cap_100T4) || (nxgep->statsp->mac_stats.lp_cap_100fdx ^ anlpar.bits.cap_100fdx) || (nxgep->statsp->mac_stats.lp_cap_100hdx ^ anlpar.bits.cap_100hdx) || (nxgep->statsp->mac_stats.lp_cap_10fdx ^ anlpar.bits.cap_10fdx) || (nxgep->statsp->mac_stats.lp_cap_10hdx ^ anlpar.bits.cap_10hdx))) { bmsr_data.bits.link_status = 0; } } } /* Workaround for link down issue */ if (bmsr_data.value == 0) { cmn_err(CE_NOTE, "!LINK DEBUG: Read zero bmsr\n"); goto nxge_check_mii_link_exit; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_check_mii_link port<0x%x> :" "BEFORE BMSR ^ nxgep->bmsr 0x%x bmsr_data 0x%x", portn, nxgep->bmsr.value, bmsr_data.value)); bmsr_ints.value = nxgep->bmsr.value ^ bmsr_data.value; nxgep->bmsr.value = bmsr_data.value; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_check_mii_link port<0x%x> CALLING " "bmsr_data 0x%x bmsr_ints.value 0x%x", portn, bmsr_data.value, bmsr_ints.value)); if ((status = nxge_mii_check(nxgep, bmsr_data, bmsr_ints, &link_up)) != NXGE_OK) { goto fail; } break; case PORT_1G_SERDES: /* * Above default is for all cases except PORT_1G_SERDES. * The default case gets information from the PHY, but a * nxge whose portmode equals PORT_1G_SERDES does not * have a PHY. */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_check_mii_link port<%d> (SERDES)", portn)); nxge_pcs_check(nxgep, portn, &link_up); break; } nxge_check_mii_link_exit: RW_EXIT(&nxgep->filter_lock); if (link_up == LINK_IS_UP) { nxge_link_is_up(nxgep); } else if (link_up == LINK_IS_DOWN) { nxge_link_is_down(nxgep); } (void) nxge_link_monitor(nxgep, LINK_MONITOR_START); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_check_mii_link port<%d>", portn)); return (NXGE_OK); fail: RW_EXIT(&nxgep->filter_lock); (void) nxge_link_monitor(nxgep, LINK_MONITOR_START); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_check_mii_link: Failed to check link port<%d>", portn)); return (status); } /*ARGSUSED*/ static nxge_status_t nxge_check_10g_link(p_nxge_t nxgep) { uint8_t portn; nxge_status_t status = NXGE_OK; boolean_t link_up; uint32_t val; npi_status_t rs; if (nxgep->nxge_magic != NXGE_MAGIC) return (NXGE_ERROR); if (nxge_check_link_stop(nxgep) == CHECK_LINK_STOP) return (NXGE_OK); portn = nxgep->mac.portnum; val = 0; rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_check_10g_link port<%d>", portn)); switch (nxgep->mac.portmode) { default: /* * Check if the phy is present in case of hot swappable phy */ if (nxgep->hot_swappable_phy) { boolean_t phy_present_now = B_FALSE; /* * If this is the 2nd Goa port, then check 2 addresses * to take care of the Goa NEM card requirements. */ if (portn == 1) { if (nxge_is_phy_present(nxgep, ALT_GOA_CLAUSE45_PORT1_ADDR, BCM8706_DEV_ID, BCM_PHY_ID_MASK)) { phy_present_now = B_TRUE; nxgep->xcvr_addr = ALT_GOA_CLAUSE45_PORT1_ADDR; goto phy_check_done; } } if (nxge_is_phy_present(nxgep, (GOA_CLAUSE45_PORT_ADDR_BASE) + portn, BCM8706_DEV_ID, BCM_PHY_ID_MASK)) { nxgep->xcvr_addr = (GOA_CLAUSE45_PORT_ADDR_BASE) + portn; phy_present_now = B_TRUE; } phy_check_done: if (nxgep->phy_absent) { if (phy_present_now) { /* * Detect, Initialize phy and do link up * set xcvr vals, link_init, nxge_init */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Hot swappable phy DETECTED!!")); nxgep->phy_absent = B_FALSE; (void) nxge_xcvr_find(nxgep); (void) nxge_link_init(nxgep); if (!(nxgep->drv_state & STATE_HW_INITIALIZED)) { status = nxge_init(nxgep); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Hot swappable " "phy present, but" " driver init" " failed...")); goto fail; } } } goto start_link_check; } else if (!phy_present_now) { /* * Phy gone, bring link down reset xcvr vals */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Hot swappable phy REMOVED!!")); nxgep->phy_absent = B_TRUE; nxgep->statsp->mac_stats.link_up = 0; nxgep->statsp->mac_stats.link_speed = 0; nxgep->statsp->mac_stats.link_duplex = 0; nxge_link_is_down(nxgep); nxgep->link_notify = B_FALSE; (void) nxge_xcvr_find(nxgep); goto start_link_check; } } if (nxgep->chip_id == MRVL88X201X_CHIP_ID) { status = nxge_check_mrvl88x2011_link(nxgep, &link_up); } else { status = nxge_check_bcm8704_link(nxgep, &link_up); } if (status != NXGE_OK) goto fail; break; case PORT_10G_SERDES: rs = npi_xmac_xpcs_read(nxgep->npi_handle, nxgep->mac.portnum, XPCS_REG_STATUS, &val); if (rs != 0) goto fail; link_up = B_FALSE; if (val & XPCS_STATUS_LANE_ALIGN) { link_up = B_TRUE; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_check_10g_link port<%d> " "XPCS_REG_STATUS2 0x%x link_up %d", portn, val, link_up)); break; } if (link_up) { if (nxgep->link_notify || nxgep->statsp->mac_stats.link_up == 0) { if (nxge_10g_link_led_on(nxgep) != NXGE_OK) goto fail; nxgep->statsp->mac_stats.link_up = 1; nxgep->statsp->mac_stats.link_speed = 10000; nxgep->statsp->mac_stats.link_duplex = 2; nxge_link_is_up(nxgep); nxgep->link_notify = B_FALSE; } } else { if (nxgep->link_notify || nxgep->statsp->mac_stats.link_up == 1) { if (nxge_10g_link_led_off(nxgep) != NXGE_OK) goto fail; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Link down cable problem")); nxgep->statsp->mac_stats.link_up = 0; nxgep->statsp->mac_stats.link_speed = 0; nxgep->statsp->mac_stats.link_duplex = 0; nxge_link_is_down(nxgep); nxgep->link_notify = B_FALSE; } } start_link_check: (void) nxge_link_monitor(nxgep, LINK_MONITOR_START); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_check_10g_link port<%d>", portn)); return (NXGE_OK); fail: (void) nxge_check_link_stop(nxgep); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_check_10g_link: Failed to check link port<%d>", portn)); return (status); } /* Declare link down */ void nxge_link_is_down(p_nxge_t nxgep) { p_nxge_stats_t statsp; char link_stat_msg[64]; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_link_is_down")); statsp = nxgep->statsp; (void) sprintf(link_stat_msg, "xcvr addr:0x%02x - link is down", statsp->mac_stats.xcvr_portn); if (nxge_no_msg == B_FALSE) { NXGE_ERROR_MSG((nxgep, NXGE_NOTE, "%s", link_stat_msg)); } mac_link_update(nxgep->mach, LINK_STATE_DOWN); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_link_is_down")); } /* Declare link up */ void nxge_link_is_up(p_nxge_t nxgep) { p_nxge_stats_t statsp; char link_stat_msg[64]; uint32_t val; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_link_is_up")); statsp = nxgep->statsp; (void) sprintf(link_stat_msg, "xcvr addr:0x%02x - link is up %d Mbps ", statsp->mac_stats.xcvr_portn, statsp->mac_stats.link_speed); if (statsp->mac_stats.link_T4) (void) strcat(link_stat_msg, "T4"); else if (statsp->mac_stats.link_duplex == 2) (void) strcat(link_stat_msg, "full duplex"); else (void) strcat(link_stat_msg, "half duplex"); /* Clean up symbol errors incurred during link transition */ if ((nxgep->mac.portmode == PORT_10G_FIBER) || (nxgep->mac.portmode == PORT_10G_SERDES)) { (void) npi_xmac_xpcs_read(nxgep->npi_handle, nxgep->mac.portnum, XPCS_REG_SYMBOL_ERR_L0_1_COUNTER, &val); (void) npi_xmac_xpcs_read(nxgep->npi_handle, nxgep->mac.portnum, XPCS_REG_SYMBOL_ERR_L2_3_COUNTER, &val); } /* * If the driver was plumbed without a link (therefore auto-negotiation * could not complete), the driver will detect a link up when a cable * conneting to a link partner is plugged into the port. By the time * link-up is detected, auto-negotiation should have completed (The * TN1010 tries to contact a link partner every 8~24ms). Here we re- * configure the Neptune/NIU according to the newly negotiated speed. * This is necessary only for the TN1010 basad device because only the * TN1010 supports dual speeds. */ if (nxgep->mac.portmode == PORT_1G_TN1010 || nxgep->mac.portmode == PORT_10G_TN1010) { (void) nxge_set_tn1010_param(nxgep); /* * nxge_xcvr_find calls nxge_get_xcvr_type (which sets * nxgep->portmode) and nxge_setup_xcvr_table (which sets * the nxgep->xcvr to the proper nxge_xcvr_table_t struct). */ if (nxge_xcvr_find(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_link_is_up: nxge_xcvr_find failed")); } /* nxge_link_init calls nxge_xcvr_init and nxge_serdes_init */ if (nxge_link_init(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_link_is_up: nxge_link_init failed")); } /* * nxge_mac_init calls many subroutines including * nxge_xif_init which sets XGMII or GMII mode */ if (nxge_mac_init(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_link_is_up: nxge_mac_init failed")); } } else { (void) nxge_xif_init(nxgep); } if (nxge_no_msg == B_FALSE) { NXGE_ERROR_MSG((nxgep, NXGE_NOTE, "%s", link_stat_msg)); } mac_link_update(nxgep->mach, LINK_STATE_UP); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_link_is_up")); } #ifdef NXGE_DEBUG /* Dump all TN1010 Status registers */ static void nxge_dump_tn1010_status_regs(p_nxge_t nxgep) { uint16_t val; nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PMA_PMD_DEV_ADDR, 1, &val); cmn_err(CE_NOTE, "PMA status1 = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PMA_PMD_DEV_ADDR, 8, &val); cmn_err(CE_NOTE, "PMA status2 = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PMA_PMD_DEV_ADDR, 129, &val); cmn_err(CE_NOTE, "10BASET-T status = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PCS_DEV_ADDR, 1, &val); cmn_err(CE_NOTE, "PCS status1 = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PCS_DEV_ADDR, 8, &val); cmn_err(CE_NOTE, "PCS status2 = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PCS_DEV_ADDR, 32, &val); cmn_err(CE_NOTE, "10GBASE-R status1 = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PCS_DEV_ADDR, 33, &val); cmn_err(CE_NOTE, "10GBASE-R Status2 = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PHYXS_DEV_ADDR, 1, &val); cmn_err(CE_NOTE, "PHYXS status1 = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PHYXS_DEV_ADDR, 8, &val); cmn_err(CE_NOTE, "PHYXS status2 = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_PHYXS_DEV_ADDR, 24, &val); cmn_err(CE_NOTE, "XGXS Lane status = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_AUTONEG_DEV_ADDR, 1, &val); cmn_err(CE_NOTE, "Autoneg status = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_AUTONEG_DEV_ADDR, 33, &val); cmn_err(CE_NOTE, "10Gbase-T An status = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_VENDOR_MMD1_DEV_ADDR, 1, &val); cmn_err(CE_NOTE, "TN1010 status = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_VENDOR_MMD1_DEV_ADDR, 8, &val); cmn_err(CE_NOTE, "Device status = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_VENDOR_MMD1_DEV_ADDR, 16, &val); cmn_err(CE_NOTE, "DDR status = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_VENDOR_MMD1_DEV_ADDR, 17, &val); cmn_err(CE_NOTE, "DDR fault status = 0x%x", val); nxge_mdio_read(nxgep, nxgep->xcvr_addr, TN1010_VENDOR_MMD1_DEV_ADDR, 11, &val); cmn_err(CE_NOTE, "Firmware Revision = 0x%x Major = 0x%x Minor = 0x%x", val, (val & 0xFF00) >> 8, val & 0x00FF); } #endif /* * Calculate the bit in the multicast address filter * that selects the given * address. * Note: For GEM, the last 8-bits are used. */ uint32_t crc32_mchash(p_ether_addr_t addr) { uint8_t *cp; uint32_t crc; uint32_t c; int byte; int bit; cp = (uint8_t *)addr; crc = (uint32_t)0xffffffff; for (byte = 0; byte < 6; byte++) { c = (uint32_t)cp[byte]; for (bit = 0; bit < 8; bit++) { if ((c & 0x1) ^ (crc & 0x1)) crc = (crc >> 1)^0xedb88320; else crc = (crc >> 1); c >>= 1; } } return ((~crc) >> (32 - HASH_BITS)); } /* Reset serdes */ nxge_status_t nxge_serdes_reset(p_nxge_t nxgep) { npi_handle_t handle; handle = nxgep->npi_handle; ESR_REG_WR(handle, ESR_RESET_REG, ESR_RESET_0 | ESR_RESET_1); drv_usecwait(500); ESR_REG_WR(handle, ESR_CONFIG_REG, 0); return (NXGE_OK); } /* * This function monitors link status using interrupt or polling. * It calls nxgep->xcvr.check_link, a member function of * nxge_xcvr_table_t. But nxgep->xcvr.check_link calls this * function back, that is why the check_link routine is * executed periodically. */ nxge_status_t nxge_link_monitor(p_nxge_t nxgep, link_mon_enable_t enable) { nxge_status_t status = NXGE_OK; /* If we are a guest domain driver, don't bother. */ if (isLDOMguest(nxgep)) return (status); /* * Return immediately if this is an imaginary XMAC port. * (At least, we don't have 4-port XMAC cards yet.) */ if ((nxgep->mac.portmode == PORT_10G_FIBER || nxgep->mac.portmode == PORT_10G_SERDES) && (nxgep->mac.portnum > 1)) return (NXGE_OK); if (nxgep->statsp == NULL) { /* stats has not been allocated. */ return (NXGE_OK); } /* Don't check link if we're in internal loopback mode */ if (nxgep->statsp->port_stats.lb_mode >= nxge_lb_serdes10g) return (NXGE_OK); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_link_monitor port<%d> enable=%d", nxgep->mac.portnum, enable)); if (enable == LINK_MONITOR_START) { if (nxgep->mac.linkchkmode == LINKCHK_INTR) { if ((status = nxge_link_intr(nxgep, LINK_INTR_START)) != NXGE_OK) goto fail; } else { timeout_id_t timerid; /* * check_link_stop means "Stop the link check", so * we return without starting the timer. */ if (nxge_check_link_stop(nxgep) == CHECK_LINK_STOP) return (NXGE_OK); /* * Otherwise fire the timer for the nxge to check * the link using the check_link function * of the nxge_xcvr_table and pass "nxgep" as the * argument to the check_link function. */ if (nxgep->xcvr.check_link) { timerid = timeout( (fptrv_t)(nxgep->xcvr.check_link), nxgep, drv_usectohz(LINK_MONITOR_PERIOD)); MUTEX_ENTER(&nxgep->poll_lock); nxgep->nxge_link_poll_timerid = timerid; MUTEX_EXIT(&nxgep->poll_lock); } else { return (NXGE_ERROR); } } } else { if (nxgep->mac.linkchkmode == LINKCHK_INTR) { if ((status = nxge_link_intr(nxgep, LINK_INTR_STOP)) != NXGE_OK) goto fail; } else { clock_t rv; MUTEX_ENTER(&nxgep->poll_lock); /* If == 0, the link monitor has */ /* never been started, or just now stopped. */ if (nxgep->nxge_link_poll_timerid == 0) { MUTEX_EXIT(&nxgep->poll_lock); return (NXGE_OK); } nxgep->poll_state = LINK_MONITOR_STOPPING; rv = cv_timedwait(&nxgep->poll_cv, &nxgep->poll_lock, ddi_get_lbolt() + drv_usectohz(LM_WAIT_MULTIPLIER * LINK_MONITOR_PERIOD)); if (rv == -1) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> stopping port %d: " "cv_timedwait(%d) timed out", nxgep->mac.portnum, nxgep->poll_state)); nxgep->poll_state = LINK_MONITOR_STOP; nxgep->nxge_link_poll_timerid = 0; } MUTEX_EXIT(&nxgep->poll_lock); } } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_link_monitor port<%d> enable=%d", nxgep->mac.portnum, enable)); return (NXGE_OK); fail: return (status); } nxge_status_t nxge_check_tn1010_link(p_nxge_t nxgep) { nxge_status_t status = NXGE_OK; nxge_link_state_t link_up; if (nxgep->nxge_magic != NXGE_MAGIC) { /* magic is 0 if driver is not attached */ return (NXGE_ERROR); } /* Link has been stopped, no need to continue */ if (nxge_check_link_stop(nxgep) == CHECK_LINK_STOP) { return (NXGE_OK); } if (nxgep->statsp->port_stats.lb_mode > nxge_lb_ext10) goto nxge_check_tn1010_link_exit; if ((status = nxge_tn1010_check(nxgep, &link_up)) != NXGE_OK) goto fail; nxge_check_tn1010_link_exit: if (link_up == LINK_IS_UP) nxge_link_is_up(nxgep); else if (link_up == LINK_IS_DOWN) nxge_link_is_down(nxgep); /* * nxge_link_monitor will call (nxgep->xcvr.check_link) * which could be THIS function. */ (void) nxge_link_monitor(nxgep, LINK_MONITOR_START); return (NXGE_OK); fail: (void) nxge_link_monitor(nxgep, LINK_MONITOR_START); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_check_tn1010_link: Failed to check link")); return (status); } /* * Fill variable "link_up" with either LINK_IS_UP or LINK_IS_DOWN. */ static nxge_status_t nxge_tn1010_check(p_nxge_t nxgep, nxge_link_state_t *link_up) { nxge_status_t status = NXGE_OK; p_nxge_stats_t statsp; uint8_t phy_port_addr, portn; uint16_t val; *link_up = LINK_NO_CHANGE; portn = NXGE_GET_PORT_NUM(nxgep->function_num); phy_port_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; statsp = nxgep->statsp; /* Check if link is up */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, TN1010_AUTONEG_DEV_ADDR, TN1010_AUTONEG_STATUS_REG, &val)) != NXGE_OK) { goto fail; } /* * nxge_link_is_up has called nxge_set_tn1010_param and set * portmode and link_speed */ if (val & TN1010_AN_LINK_STAT_BIT) { if (nxgep->link_notify || nxgep->statsp->mac_stats.link_up == 0) { statsp->mac_stats.link_up = 1; statsp->mac_stats.link_duplex = 2; *link_up = LINK_IS_UP; nxgep->link_notify = B_FALSE; } } else { if (nxgep->link_notify || nxgep->statsp->mac_stats.link_up == 1) { statsp->mac_stats.link_up = 0; statsp->mac_stats.link_speed = 0; statsp->mac_stats.link_duplex = 0; *link_up = LINK_IS_DOWN; nxgep->link_notify = B_FALSE; } } return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_tn1010_check: Unable to check TN1010")); return (status); } /* Set promiscous mode */ nxge_status_t nxge_set_promisc(p_nxge_t nxgep, boolean_t on) { nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_set_promisc: on %d", on)); nxgep->filter.all_phys_cnt = ((on) ? 1 : 0); RW_ENTER_WRITER(&nxgep->filter_lock); if ((status = nxge_rx_mac_disable(nxgep)) != NXGE_OK) { goto fail; } if ((status = nxge_rx_mac_enable(nxgep)) != NXGE_OK) { goto fail; } RW_EXIT(&nxgep->filter_lock); if (on) nxgep->statsp->mac_stats.promisc = B_TRUE; else nxgep->statsp->mac_stats.promisc = B_FALSE; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_set_promisc")); return (NXGE_OK); fail: RW_EXIT(&nxgep->filter_lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_set_promisc: " "Unable to set promisc (%d)", on)); return (status); } /*ARGSUSED*/ uint_t nxge_mif_intr(void *arg1, void *arg2) { #ifdef NXGE_DEBUG p_nxge_t nxgep = (p_nxge_t)arg2; #endif #if NXGE_MIF p_nxge_ldv_t ldvp = (p_nxge_ldv_t)arg1; uint32_t status; npi_handle_t handle; uint8_t portn; p_nxge_stats_t statsp; #endif #ifdef NXGE_MIF if (arg2 == NULL || (void *)ldvp->nxgep != arg2) { nxgep = ldvp->nxgep; } nxgep = ldvp->nxgep; #endif NXGE_DEBUG_MSG((nxgep, INT_CTL, "==> nxge_mif_intr")); NXGE_DEBUG_MSG((nxgep, INT_CTL, "<== nxge_mif_intr")); return (DDI_INTR_CLAIMED); mif_intr_fail: NXGE_DEBUG_MSG((nxgep, INT_CTL, "<== nxge_mif_intr")); return (DDI_INTR_UNCLAIMED); } /*ARGSUSED*/ uint_t nxge_mac_intr(void *arg1, void *arg2) { p_nxge_t nxgep = (p_nxge_t)arg2; p_nxge_ldv_t ldvp = (p_nxge_ldv_t)arg1; p_nxge_ldg_t ldgp; uint32_t status; npi_handle_t handle; uint8_t portn; p_nxge_stats_t statsp; npi_status_t rs = NPI_SUCCESS; if (arg2 == NULL || (void *)ldvp->nxgep != arg2) { nxgep = ldvp->nxgep; } ldgp = ldvp->ldgp; NXGE_DEBUG_MSG((nxgep, INT_CTL, "==> nxge_mac_intr: " "group %d", ldgp->ldg)); handle = NXGE_DEV_NPI_HANDLE(nxgep); /* * This interrupt handler is for a specific * mac port. */ statsp = (p_nxge_stats_t)nxgep->statsp; portn = nxgep->mac.portnum; NXGE_DEBUG_MSG((nxgep, INT_CTL, "==> nxge_mac_intr: reading mac stats: port<%d>", portn)); if (nxgep->mac.porttype == PORT_TYPE_XMAC) { rs = npi_xmac_tx_get_istatus(handle, portn, (xmac_tx_iconfig_t *)&status); if (rs != NPI_SUCCESS) goto npi_fail; if (status & ICFG_XMAC_TX_ALL) { if (status & ICFG_XMAC_TX_UNDERRUN) { statsp->xmac_stats.tx_underflow_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_TXMAC_UNDERFLOW); } if (status & ICFG_XMAC_TX_MAX_PACKET_ERR) { statsp->xmac_stats.tx_maxpktsize_err++; /* * Do not send FMA ereport because this * error does not indicate HW failure. */ } if (status & ICFG_XMAC_TX_OVERFLOW) { statsp->xmac_stats.tx_overflow_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_TXMAC_OVERFLOW); } if (status & ICFG_XMAC_TX_FIFO_XFR_ERR) { statsp->xmac_stats.tx_fifo_xfr_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_TXMAC_TXFIFO_XFR_ERR); } if (status & ICFG_XMAC_TX_BYTE_CNT_EXP) { statsp->xmac_stats.tx_byte_cnt += XTXMAC_BYTE_CNT_MASK; } if (status & ICFG_XMAC_TX_FRAME_CNT_EXP) { statsp->xmac_stats.tx_frame_cnt += XTXMAC_FRM_CNT_MASK; } } rs = npi_xmac_rx_get_istatus(handle, portn, (xmac_rx_iconfig_t *)&status); if (rs != NPI_SUCCESS) goto npi_fail; if (status & ICFG_XMAC_RX_ALL) { if (status & ICFG_XMAC_RX_OVERFLOW) statsp->xmac_stats.rx_overflow_err++; if (status & ICFG_XMAC_RX_UNDERFLOW) { statsp->xmac_stats.rx_underflow_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_RXMAC_UNDERFLOW); } /* * Do not send FMA ereport for the following 3 errors * because they do not indicate HW failures. */ if (status & ICFG_XMAC_RX_CRC_ERR_CNT_EXP) { statsp->xmac_stats.rx_crc_err_cnt += XRXMAC_CRC_ER_CNT_MASK; } if (status & ICFG_XMAC_RX_LEN_ERR_CNT_EXP) { statsp->xmac_stats.rx_len_err_cnt += MAC_LEN_ER_CNT_MASK; } if (status & ICFG_XMAC_RX_VIOL_ERR_CNT_EXP) { statsp->xmac_stats.rx_viol_err_cnt += XRXMAC_CD_VIO_CNT_MASK; } if (status & ICFG_XMAC_RX_OCT_CNT_EXP) { statsp->xmac_stats.rx_byte_cnt += XRXMAC_BT_CNT_MASK; } if (status & ICFG_XMAC_RX_HST_CNT1_EXP) { statsp->xmac_stats.rx_hist1_cnt += XRXMAC_HIST_CNT1_MASK; } if (status & ICFG_XMAC_RX_HST_CNT2_EXP) { statsp->xmac_stats.rx_hist2_cnt += XRXMAC_HIST_CNT2_MASK; } if (status & ICFG_XMAC_RX_HST_CNT3_EXP) { statsp->xmac_stats.rx_hist3_cnt += XRXMAC_HIST_CNT3_MASK; } if (status & ICFG_XMAC_RX_HST_CNT4_EXP) { statsp->xmac_stats.rx_hist4_cnt += XRXMAC_HIST_CNT4_MASK; } if (status & ICFG_XMAC_RX_HST_CNT5_EXP) { statsp->xmac_stats.rx_hist5_cnt += XRXMAC_HIST_CNT5_MASK; } if (status & ICFG_XMAC_RX_HST_CNT6_EXP) { statsp->xmac_stats.rx_hist6_cnt += XRXMAC_HIST_CNT6_MASK; } if (status & ICFG_XMAC_RX_BCAST_CNT_EXP) { statsp->xmac_stats.rx_broadcast_cnt += XRXMAC_BC_FRM_CNT_MASK; } if (status & ICFG_XMAC_RX_MCAST_CNT_EXP) { statsp->xmac_stats.rx_mult_cnt += XRXMAC_MC_FRM_CNT_MASK; } /* * Do not send FMA ereport for the following 3 errors * because they do not indicate HW failures. */ if (status & ICFG_XMAC_RX_FRAG_CNT_EXP) { statsp->xmac_stats.rx_frag_cnt += XRXMAC_FRAG_CNT_MASK; } if (status & ICFG_XMAC_RX_ALIGNERR_CNT_EXP) { statsp->xmac_stats.rx_frame_align_err_cnt += XRXMAC_AL_ER_CNT_MASK; } if (status & ICFG_XMAC_RX_LINK_FLT_CNT_EXP) { statsp->xmac_stats.rx_linkfault_err_cnt += XMAC_LINK_FLT_CNT_MASK; } if (status & ICFG_XMAC_RX_REMOTE_FLT_DET) { statsp->xmac_stats.rx_remotefault_err++; } if (status & ICFG_XMAC_RX_LOCAL_FLT_DET) { statsp->xmac_stats.rx_localfault_err++; } } rs = npi_xmac_ctl_get_istatus(handle, portn, (xmac_ctl_iconfig_t *)&status); if (rs != NPI_SUCCESS) goto npi_fail; if (status & ICFG_XMAC_CTRL_ALL) { if (status & ICFG_XMAC_CTRL_PAUSE_RCVD) statsp->xmac_stats.rx_pause_cnt++; if (status & ICFG_XMAC_CTRL_PAUSE_STATE) statsp->xmac_stats.tx_pause_state++; if (status & ICFG_XMAC_CTRL_NOPAUSE_STATE) statsp->xmac_stats.tx_nopause_state++; } } else if (nxgep->mac.porttype == PORT_TYPE_BMAC) { rs = npi_bmac_tx_get_istatus(handle, portn, (bmac_tx_iconfig_t *)&status); if (rs != NPI_SUCCESS) goto npi_fail; if (status & ICFG_BMAC_TX_ALL) { if (status & ICFG_BMAC_TX_UNDERFLOW) { statsp->bmac_stats.tx_underrun_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_TXMAC_UNDERFLOW); } if (status & ICFG_BMAC_TX_MAXPKTSZ_ERR) { statsp->bmac_stats.tx_max_pkt_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_TXMAC_MAX_PKT_ERR); } if (status & ICFG_BMAC_TX_BYTE_CNT_EXP) { statsp->bmac_stats.tx_byte_cnt += BTXMAC_BYTE_CNT_MASK; } if (status & ICFG_BMAC_TX_FRAME_CNT_EXP) { statsp->bmac_stats.tx_frame_cnt += BTXMAC_FRM_CNT_MASK; } } rs = npi_bmac_rx_get_istatus(handle, portn, (bmac_rx_iconfig_t *)&status); if (rs != NPI_SUCCESS) goto npi_fail; if (status & ICFG_BMAC_RX_ALL) { if (status & ICFG_BMAC_RX_OVERFLOW) { statsp->bmac_stats.rx_overflow_err++; } if (status & ICFG_BMAC_RX_FRAME_CNT_EXP) { statsp->bmac_stats.rx_frame_cnt += RXMAC_FRM_CNT_MASK; } if (status & ICFG_BMAC_RX_CRC_ERR_CNT_EXP) { statsp->bmac_stats.rx_crc_err_cnt += BMAC_CRC_ER_CNT_MASK; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_RXMAC_CRC_ERRCNT_EXP); } if (status & ICFG_BMAC_RX_LEN_ERR_CNT_EXP) { statsp->bmac_stats.rx_len_err_cnt += MAC_LEN_ER_CNT_MASK; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_RXMAC_LENGTH_ERRCNT_EXP); } if (status & ICFG_BMAC_RX_VIOL_ERR_CNT_EXP) statsp->bmac_stats.rx_viol_err_cnt += BMAC_CD_VIO_CNT_MASK; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_RXMAC_VIOL_ERRCNT_EXP); } if (status & ICFG_BMAC_RX_BYTE_CNT_EXP) { statsp->bmac_stats.rx_byte_cnt += BRXMAC_BYTE_CNT_MASK; } if (status & ICFG_BMAC_RX_ALIGNERR_CNT_EXP) { statsp->bmac_stats.rx_align_err_cnt += BMAC_AL_ER_CNT_MASK; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_RXMAC_ALIGN_ECNT_EXP); } rs = npi_bmac_ctl_get_istatus(handle, portn, (bmac_ctl_iconfig_t *)&status); if (rs != NPI_SUCCESS) goto npi_fail; if (status & ICFG_BMAC_CTL_ALL) { if (status & ICFG_BMAC_CTL_RCVPAUSE) statsp->bmac_stats.rx_pause_cnt++; if (status & ICFG_BMAC_CTL_INPAUSE_ST) statsp->bmac_stats.tx_pause_state++; if (status & ICFG_BMAC_CTL_INNOTPAUSE_ST) statsp->bmac_stats.tx_nopause_state++; } } if (ldgp->nldvs == 1) { (void) npi_intr_ldg_mgmt_set(handle, ldgp->ldg, B_TRUE, ldgp->ldg_timer); } NXGE_DEBUG_MSG((nxgep, INT_CTL, "<== nxge_mac_intr")); return (DDI_INTR_CLAIMED); npi_fail: NXGE_ERROR_MSG((nxgep, INT_CTL, "<== nxge_mac_intr")); return (DDI_INTR_UNCLAIMED); } nxge_status_t nxge_check_bcm8704_link(p_nxge_t nxgep, boolean_t *link_up) { uint8_t phy_port_addr; nxge_status_t status = NXGE_OK; boolean_t rx_sig_ok; boolean_t pcs_blk_lock; boolean_t link_align; uint16_t val1, val2, val3; #ifdef NXGE_DEBUG_SYMBOL_ERR uint16_t val_debug; uint16_t val; #endif phy_port_addr = nxgep->statsp->mac_stats.xcvr_portn; #ifdef NXGE_DEBUG_SYMBOL_ERR /* Check Device 3 Register Device 3 0xC809 */ (void) nxge_mdio_read(nxgep, phy_port_addr, 0x3, 0xC809, &val_debug); if ((val_debug & ~0x200) != 0) { cmn_err(CE_NOTE, "!Port%d BCM8704 Dev3 Reg 0xc809 = 0x%x\n", nxgep->mac.portnum, val_debug); (void) nxge_mdio_read(nxgep, phy_port_addr, 0x4, 0x18, &val_debug); cmn_err(CE_NOTE, "!Port%d BCM8704 Dev4 Reg 0x18 = 0x%x\n", nxgep->mac.portnum, val_debug); } (void) npi_xmac_xpcs_read(nxgep->npi_handle, nxgep->mac.portnum, XPCS_REG_DESCWERR_COUNTER, &val); if (val != 0) cmn_err(CE_NOTE, "!XPCS DESCWERR = 0x%x\n", val); (void) npi_xmac_xpcs_read(nxgep->npi_handle, nxgep->mac.portnum, XPCS_REG_SYMBOL_ERR_L0_1_COUNTER, &val); if (val != 0) cmn_err(CE_NOTE, "!XPCS SYMBOL_ERR_L0_1 = 0x%x\n", val); (void) npi_xmac_xpcs_read(nxgep->npi_handle, nxgep->mac.portnum, XPCS_REG_SYMBOL_ERR_L2_3_COUNTER, &val); if (val != 0) cmn_err(CE_NOTE, "!XPCS SYMBOL_ERR_L2_3 = 0x%x\n", val); #endif /* Check from BCM8704 if 10G link is up or down */ /* Check Device 1 Register 0xA bit0 */ status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PMA_PMD_DEV_ADDR, BCM8704_PMD_RECEIVE_SIG_DETECT, &val1); if (status != NXGE_OK) goto fail; rx_sig_ok = ((val1 & GLOB_PMD_RX_SIG_OK) ? B_TRUE : B_FALSE); /* Check Device 3 Register 0x20 bit0 */ if ((status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PCS_DEV_ADDR, BCM8704_10GBASE_R_PCS_STATUS_REG, &val2)) != NPI_SUCCESS) goto fail; pcs_blk_lock = ((val2 & PCS_10GBASE_R_PCS_BLK_LOCK) ? B_TRUE : B_FALSE); /* Check Device 4 Register 0x18 bit12 */ status = nxge_mdio_read(nxgep, phy_port_addr, BCM8704_PHYXS_ADDR, BCM8704_PHYXS_XGXS_LANE_STATUS_REG, &val3); if (status != NXGE_OK) goto fail; switch (nxgep->chip_id) { case BCM8704_CHIP_ID: link_align = (val3 == (XGXS_LANE_ALIGN_STATUS | XGXS_LANE3_SYNC | XGXS_LANE2_SYNC | XGXS_LANE1_SYNC | XGXS_LANE0_SYNC | 0x400)) ? B_TRUE : B_FALSE; break; case BCM8706_CHIP_ID: link_align = ((val3 & XGXS_LANE_ALIGN_STATUS) && (val3 & XGXS_LANE3_SYNC) && (val3 & XGXS_LANE2_SYNC) && (val3 & XGXS_LANE1_SYNC) && (val3 & XGXS_LANE0_SYNC)) ? B_TRUE : B_FALSE; break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_check_bcm8704_link:" "Unknown chip ID [0x%x]", nxgep->chip_id)); goto fail; } #ifdef NXGE_DEBUG_ALIGN_ERR /* Temp workaround for link down issue */ if (pcs_blk_lock == B_FALSE) { if (val2 != 0x4) { pcs_blk_lock = B_TRUE; cmn_err(CE_NOTE, "!LINK DEBUG: port%d PHY Dev3 " "Reg 0x20 = 0x%x\n", nxgep->mac.portnum, val2); } } if (link_align == B_FALSE) { if (val3 != 0x140f) { link_align = B_TRUE; cmn_err(CE_NOTE, "!LINK DEBUG: port%d PHY Dev4 " "Reg 0x18 = 0x%x\n", nxgep->mac.portnum, val3); } } if (rx_sig_ok == B_FALSE) { if ((val2 == 0) || (val3 == 0)) { rx_sig_ok = B_TRUE; cmn_err(CE_NOTE, "!LINK DEBUG: port %d Dev3 or Dev4 read zero\n", nxgep->mac.portnum); } } #endif *link_up = ((rx_sig_ok == B_TRUE) && (pcs_blk_lock == B_TRUE) && (link_align == B_TRUE)) ? B_TRUE : B_FALSE; return (NXGE_OK); fail: return (status); } static nxge_status_t nxge_check_mrvl88x2011_link(p_nxge_t nxgep, boolean_t *link_up) { uint8_t phy; nxge_status_t status = NXGE_OK; boolean_t pma_status; boolean_t pcs_status; boolean_t xgxs_status; uint16_t val; phy = nxgep->statsp->mac_stats.xcvr_portn; MRVL88X2011_RD(nxgep, phy, MRVL_88X2011_USER_DEV1_ADDR, MRVL_88X2011_10G_PMD_STAT_2, &val); *link_up = B_FALSE; /* Check from Marvell 88X2011 if 10G link is up or down */ /* Check PMA/PMD Register: 1.0001.2 == 1 */ MRVL88X2011_RD(nxgep, phy, MRVL_88X2011_USER_DEV1_ADDR, MRVL_88X2011_PMA_PMD_STAT_1, &val); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_check_mrvl88x2011_link: pmd=0x%x", val)); pma_status = ((val & MRVL_88X2011_LNK_STATUS_OK) ? B_TRUE : B_FALSE); /* Check PMC Register : 3.0001.2 == 1: read twice */ MRVL88X2011_RD(nxgep, phy, MRVL_88X2011_USER_DEV3_ADDR, MRVL_88X2011_PMA_PMD_STAT_1, &val); MRVL88X2011_RD(nxgep, phy, MRVL_88X2011_USER_DEV3_ADDR, MRVL_88X2011_PMA_PMD_STAT_1, &val); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_check_mrvl88x2011_link: pcs=0x%x", val)); pcs_status = ((val & MRVL_88X2011_LNK_STATUS_OK) ? B_TRUE : B_FALSE); /* Check XGXS Register : 4.0018.[0-3,12] */ MRVL88X2011_RD(nxgep, phy, MRVL_88X2011_USER_DEV4_ADDR, MRVL_88X2011_10G_XGXS_LANE_STAT, &val); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_check_mrvl88x2011_link: xgxs=0x%x", val)); xgxs_status = (val == (XGXS_LANE_ALIGN_STATUS | XGXS_LANE3_SYNC | XGXS_LANE2_SYNC | XGXS_LANE1_SYNC | XGXS_LANE0_SYNC | XGXS_PATTERN_TEST_ABILITY | XGXS_LANE_STAT_MAGIC)) ? B_TRUE : B_FALSE; *link_up = (pma_status && pcs_status && xgxs_status) ? B_TRUE : B_FALSE; fail: if (*link_up == B_FALSE) { /* PCS OFF */ nxge_mrvl88x2011_led(nxgep, MRVL_88X2011_LED_CTL_OFF); } else { /* PCS Activity */ nxge_mrvl88x2011_led(nxgep, MRVL_88X2011_LED_CTL_PCS_ACT); } NXGE_DEBUG_MSG((nxgep, MAC_CTL, " <== nxge_check_mrvl88x2011_link: up=%d", *link_up)); return (status); } nxge_status_t nxge_10g_link_led_on(p_nxge_t nxgep) { if (npi_xmac_xif_led(nxgep->npi_handle, nxgep->mac.portnum, B_TRUE) != NPI_SUCCESS) return (NXGE_ERROR); else return (NXGE_OK); } nxge_status_t nxge_10g_link_led_off(p_nxge_t nxgep) { if (npi_xmac_xif_led(nxgep->npi_handle, nxgep->mac.portnum, B_FALSE) != NPI_SUCCESS) return (NXGE_ERROR); else return (NXGE_OK); } static boolean_t nxge_is_phy_present(p_nxge_t nxgep, int addr, uint32_t id, uint32_t mask) { uint32_t pma_pmd_id = 0; uint32_t pcs_id = 0; uint32_t phy_id = 0; pma_pmd_id = nxge_get_cl45_pma_pmd_id(nxgep, addr); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_is_phy_present: pma_pmd_id[0x%x]", pma_pmd_id)); if ((pma_pmd_id & mask) == (id & mask)) goto found_phy; pcs_id = nxge_get_cl45_pcs_id(nxgep, addr); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_is_phy_present: pcs_id[0x%x]", pcs_id)); if ((pcs_id & mask) == (id & mask)) goto found_phy; phy_id = nxge_get_cl22_phy_id(nxgep, addr); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_is_phy_present: phy_id[0x%x]", phy_id)); if ((phy_id & mask) == (id & mask)) goto found_phy; return (B_FALSE); found_phy: return (B_TRUE); } /* Check if the given id read using the given MDIO Clause is supported */ static boolean_t nxge_is_supported_phy(uint32_t id, uint8_t type) { int i; boolean_t found = B_FALSE; switch (type) { case CLAUSE_45_TYPE: for (i = 0; i < NUM_CLAUSE_45_IDS; i++) { if (((nxge_supported_cl45_ids[i] & BCM_PHY_ID_MASK) == (id & BCM_PHY_ID_MASK)) || (TN1010_DEV_ID == (id & TN1010_DEV_ID_MASK))) { found = B_TRUE; break; } } break; case CLAUSE_22_TYPE: for (i = 0; i < NUM_CLAUSE_22_IDS; i++) { if ((nxge_supported_cl22_ids[i] & BCM_PHY_ID_MASK) == (id & BCM_PHY_ID_MASK)) { found = B_TRUE; break; } } break; default: break; } return (found); } static uint32_t nxge_get_cl45_pma_pmd_id(p_nxge_t nxgep, int phy_port) { uint16_t val1 = 0; uint16_t val2 = 0; uint32_t pma_pmd_dev_id = 0; npi_handle_t handle = NXGE_DEV_NPI_HANDLE(nxgep); MUTEX_ENTER(&nxgep->nxge_hw_p->nxge_mdio_lock); (void) npi_mac_mif_mdio_read(handle, phy_port, NXGE_PMA_PMD_DEV_ADDR, NXGE_DEV_ID_REG_1, &val1); (void) npi_mac_mif_mdio_read(handle, phy_port, NXGE_PMA_PMD_DEV_ADDR, NXGE_DEV_ID_REG_2, &val2); MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); /* Concatenate the Device ID stored in two registers. */ pma_pmd_dev_id = val1; pma_pmd_dev_id = (pma_pmd_dev_id << 16); pma_pmd_dev_id |= val2; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "port[%d] PMA/PMD " "devid[0x%llx]", phy_port, pma_pmd_dev_id)); return (pma_pmd_dev_id); } static uint32_t nxge_get_cl45_pcs_id(p_nxge_t nxgep, int phy_port) { uint16_t val1 = 0; uint16_t val2 = 0; uint32_t pcs_dev_id = 0; npi_handle_t handle = NXGE_DEV_NPI_HANDLE(nxgep); MUTEX_ENTER(&nxgep->nxge_hw_p->nxge_mdio_lock); (void) npi_mac_mif_mdio_read(handle, phy_port, NXGE_PCS_DEV_ADDR, NXGE_DEV_ID_REG_1, &val1); (void) npi_mac_mif_mdio_read(handle, phy_port, NXGE_PCS_DEV_ADDR, NXGE_DEV_ID_REG_2, &val2); MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); pcs_dev_id = val1; pcs_dev_id = (pcs_dev_id << 16); pcs_dev_id |= val2; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "port[%d] PCS " "devid[0x%llx]", phy_port, pcs_dev_id)); return (pcs_dev_id); } static uint32_t nxge_get_cl22_phy_id(p_nxge_t nxgep, int phy_port) { uint16_t val1 = 0; uint16_t val2 = 0; uint32_t phy_id = 0; npi_handle_t handle = NXGE_DEV_NPI_HANDLE(nxgep); npi_status_t npi_status = NPI_SUCCESS; MUTEX_ENTER(&nxgep->nxge_hw_p->nxge_mdio_lock); npi_status = npi_mac_mif_mii_read(handle, phy_port, NXGE_PHY_ID_REG_1, &val1); if (npi_status != NPI_SUCCESS) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "port[%d] " "clause 22 read to reg 2 failed!!!")); goto exit; } npi_status = npi_mac_mif_mii_read(handle, phy_port, NXGE_PHY_ID_REG_2, &val2); if (npi_status != 0) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "port[%d] " "clause 22 read to reg 3 failed!!!")); goto exit; } phy_id = val1; phy_id = (phy_id << 16); phy_id |= val2; exit: MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "port[%d] PHY ID [0x%llx]", phy_port, phy_id)); return (phy_id); } /* * Scan the PHY ports 0 through 31 to get the PHY ID using Clause 22 MDIO * read and the PMA/PMD device ID and the PCS device ID using Clause 45 MDIO * read. Then use the values obtained to determine the phy type of each port * and the Neptune type. * * This function sets hw_p->xcvr_addr[i] for future MDIO access and set * hw_p->niu_type for each nxge instance to figure out nxgep->mac.portmode * in case the portmode information is not available via OBP, nxge.conf, * VPD or SEEPROM. */ nxge_status_t nxge_scan_ports_phy(p_nxge_t nxgep, p_nxge_hw_list_t hw_p) { int i, j, l; uint32_t pma_pmd_dev_id = 0; uint32_t pcs_dev_id = 0; uint32_t phy_id = 0; uint32_t port_pma_pmd_dev_id[NXGE_PORTS_NEPTUNE]; uint32_t port_pcs_dev_id[NXGE_PORTS_NEPTUNE]; uint32_t port_phy_id[NXGE_PORTS_NEPTUNE]; uint8_t pma_pmd_dev_fd[NXGE_MAX_PHY_PORTS]; uint8_t pcs_dev_fd[NXGE_MAX_PHY_PORTS]; uint8_t phy_fd_arr[NXGE_MAX_PHY_PORTS]; uint8_t port_fd_arr[NXGE_MAX_PHY_PORTS]; uint8_t total_port_fd, total_phy_fd; uint8_t num_xaui; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_scan_ports_phy: ")); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_scan_ports_phy: nxge niu_type[0x%x]", nxgep->niu_type)); if (isLDOMguest(nxgep)) { hw_p->niu_type = NIU_TYPE_NONE; hw_p->platform_type = P_NEPTUNE_NONE; return (NXGE_OK); } j = l = 0; total_port_fd = total_phy_fd = 0; /* * Clause 45 and Clause 22 port/phy addresses 0 through 5 are reserved * for on chip serdes usages. "i" in the following for loop starts at 6. */ for (i = NXGE_EXT_PHY_PORT_ST; i < NXGE_MAX_PHY_PORTS; i++) { pma_pmd_dev_id = nxge_get_cl45_pma_pmd_id(nxgep, i); if (nxge_is_supported_phy(pma_pmd_dev_id, CLAUSE_45_TYPE)) { pma_pmd_dev_fd[i] = 1; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "port[%d] " "PMA/PMD dev %x found", i, pma_pmd_dev_id)); if (j < NXGE_PORTS_NEPTUNE) { if ((pma_pmd_dev_id & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) { port_pma_pmd_dev_id[j] = TN1010_DEV_ID; } else { port_pma_pmd_dev_id[j] = pma_pmd_dev_id & BCM_PHY_ID_MASK; } port_fd_arr[j] = (uint8_t)i; j++; } } else { pma_pmd_dev_fd[i] = 0; } pcs_dev_id = nxge_get_cl45_pcs_id(nxgep, i); if (nxge_is_supported_phy(pcs_dev_id, CLAUSE_45_TYPE)) { pcs_dev_fd[i] = 1; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "port[%d] PCS " "dev %x found", i, pcs_dev_id)); if (pma_pmd_dev_fd[i] == 1) { if ((pcs_dev_id & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) { port_pcs_dev_id[j - 1] = TN1010_DEV_ID; } else { port_pcs_dev_id[j - 1] = pcs_dev_id & BCM_PHY_ID_MASK; } } else { if (j < NXGE_PORTS_NEPTUNE) { if ((pcs_dev_id & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) { port_pcs_dev_id[j] = TN1010_DEV_ID; } else { port_pcs_dev_id[j] = pcs_dev_id & BCM_PHY_ID_MASK; } port_fd_arr[j] = (uint8_t)i; j++; } } } else { pcs_dev_fd[i] = 0; } if (pcs_dev_fd[i] || pma_pmd_dev_fd[i]) { total_port_fd ++; } phy_id = nxge_get_cl22_phy_id(nxgep, i); if (nxge_is_supported_phy(phy_id, CLAUSE_22_TYPE)) { total_phy_fd ++; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "port[%d] PHY ID" "%x found", i, phy_id)); if (l < NXGE_PORTS_NEPTUNE) { if ((phy_id & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) { port_phy_id[l] = TN1010_DEV_ID; } else { port_phy_id[l] = phy_id & BCM_PHY_ID_MASK; } phy_fd_arr[l] = (uint8_t)i; l++; } } } switch (total_port_fd) { case 2: switch (total_phy_fd) { case 2: /* 2 10G, 2 1G RGMII Fiber / copper */ if ((((port_pcs_dev_id[0] == PHY_BCM8704_FAMILY) && (port_pcs_dev_id[1] == PHY_BCM8704_FAMILY)) || ((port_pma_pmd_dev_id[0] == PHY_BCM8704_FAMILY) && (port_pma_pmd_dev_id[1] == PHY_BCM8704_FAMILY))) && ((port_phy_id[0] == PHY_BCM5482_FAMILY) && (port_phy_id[1] == PHY_BCM5482_FAMILY))) { switch (hw_p->platform_type) { case P_NEPTUNE_ROCK: hw_p->niu_type = NEPTUNE_2_10GF_2_1GC; /* * ROCK platform has assigned a lower * addr to port 1. (port 0 = 0x9 and * port 1 = 0x8). */ hw_p->xcvr_addr[1] = port_fd_arr[0]; hw_p->xcvr_addr[0] = port_fd_arr[1]; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Rock with 2 10G, 2 1GC")); break; case P_NEPTUNE_NONE: default: hw_p->platform_type = P_NEPTUNE_GENERIC; hw_p->niu_type = NEPTUNE_2_10GF_2_1GRF; hw_p->xcvr_addr[0] = port_fd_arr[0]; hw_p->xcvr_addr[1] = port_fd_arr[1]; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "ARTM card with 2 10G, 2 1GF")); break; } hw_p->xcvr_addr[2] = phy_fd_arr[0]; hw_p->xcvr_addr[3] = phy_fd_arr[1]; } else { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unsupported neptune type 1")); goto error_exit; } break; case 1: /* TODO - 2 10G, 1 1G */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 2 10G, 1 1G")); goto error_exit; case 0: /* * 2 10G: 2XGF NIC, Marvell, Goa, Huron with 2 XAUI * cards, etc. */ if (((port_pcs_dev_id[0] == PHY_BCM8704_FAMILY) && (port_pcs_dev_id[1] == PHY_BCM8704_FAMILY)) || ((port_pma_pmd_dev_id[0] == PHY_BCM8704_FAMILY) && (port_pma_pmd_dev_id[1] == PHY_BCM8704_FAMILY)) || ((port_pcs_dev_id[0] == MARVELL_88X201X_PHY_ID) && (port_pcs_dev_id[1] == MARVELL_88X201X_PHY_ID)) || ((port_pma_pmd_dev_id[0] == MARVELL_88X201X_PHY_ID) && (port_pma_pmd_dev_id[1] == MARVELL_88X201X_PHY_ID))) { /* * Check the first phy port address against * the known phy start addresses to determine * the platform type. */ switch (port_fd_arr[0]) { case NEPTUNE_CLAUSE45_PORT_ADDR_BASE: /* * The Marvell case also falls into * this case as * MRVL88X2011_NEPTUNE_PORT_ADDR_BASE * == NEPTUNE_CLAUSE45_PORT_ADDR_BASE. * This is OK for the 2 10G case. */ hw_p->niu_type = NEPTUNE_2_10GF; hw_p->platform_type = P_NEPTUNE_ATLAS_2PORT; break; case GOA_CLAUSE45_PORT_ADDR_BASE: if (hw_p->platform_type != P_NEPTUNE_NIU) { hw_p->platform_type = P_NEPTUNE_GENERIC; hw_p->niu_type = NEPTUNE_2_10GF; } break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unsupported neptune type 2 - 1")); goto error_exit; } for (i = 0; i < 2; i++) { hw_p->xcvr_addr[i] = port_fd_arr[i]; } /* Both XAUI slots have copper XAUI cards */ } else if ((((port_pcs_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) && ((port_pcs_dev_id[1] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID)) || (((port_pma_pmd_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) && ((port_pma_pmd_dev_id[1] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID))) { hw_p->niu_type = NEPTUNE_2_TN1010; hw_p->xcvr_addr[0] = port_fd_arr[0]; hw_p->xcvr_addr[1] = port_fd_arr[1]; /* Slot0 has fiber XAUI, slot1 has copper XAUI */ } else if ((port_pcs_dev_id[0] == PHY_BCM8704_FAMILY && (port_pcs_dev_id[1] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) || (port_pma_pmd_dev_id[0] == PHY_BCM8704_FAMILY && (port_pma_pmd_dev_id[1] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID)) { hw_p->niu_type = NEPTUNE_1_10GF_1_TN1010; hw_p->xcvr_addr[0] = port_fd_arr[0]; hw_p->xcvr_addr[1] = port_fd_arr[1]; /* Slot0 has copper XAUI, slot1 has fiber XAUI */ } else if ((port_pcs_dev_id[1] == PHY_BCM8704_FAMILY && (port_pcs_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) || (port_pma_pmd_dev_id[1] == PHY_BCM8704_FAMILY && (port_pma_pmd_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID)) { hw_p->niu_type = NEPTUNE_1_TN1010_1_10GF; hw_p->xcvr_addr[0] = port_fd_arr[0]; hw_p->xcvr_addr[1] = port_fd_arr[1]; } else { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 2")); goto error_exit; } break; case 4: if (nxge_get_num_of_xaui( port_pma_pmd_dev_id, port_pcs_dev_id, port_phy_id, &num_xaui) == NXGE_ERROR) { goto error_exit; } if (num_xaui != 2) goto error_exit; /* * Maramba with 2 XAUIs (either fiber or copper) * * Check the first phy port address against * the known phy start addresses to determine * the platform type. */ switch (phy_fd_arr[0]) { case MARAMBA_P0_CLAUSE22_PORT_ADDR_BASE: hw_p->platform_type = P_NEPTUNE_MARAMBA_P0; break; case MARAMBA_P1_CLAUSE22_PORT_ADDR_BASE: hw_p->platform_type = P_NEPTUNE_MARAMBA_P1; break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unknown port %d...Cannot " "determine platform type", i)); goto error_exit; } hw_p->xcvr_addr[0] = port_fd_arr[0]; hw_p->xcvr_addr[1] = port_fd_arr[1]; hw_p->xcvr_addr[2] = phy_fd_arr[2]; hw_p->xcvr_addr[3] = phy_fd_arr[3]; /* slot0 has fiber XAUI, slot1 has Cu XAUI */ if (port_pcs_dev_id[0] == PHY_BCM8704_FAMILY && (port_pcs_dev_id[1] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) { hw_p->niu_type = NEPTUNE_1_10GF_1_TN1010_2_1GC; /* slot0 has Cu XAUI, slot1 has fiber XAUI */ } else if (((port_pcs_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) && port_pcs_dev_id[1] == PHY_BCM8704_FAMILY) { hw_p->niu_type = NEPTUNE_1_TN1010_1_10GF_2_1GC; /* Both slots have fiber XAUI */ } else if (port_pcs_dev_id[0] == PHY_BCM8704_FAMILY && port_pcs_dev_id[1] == PHY_BCM8704_FAMILY) { hw_p->niu_type = NEPTUNE_2_10GF_2_1GC; /* Both slots have copper XAUI */ } else if (((port_pcs_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) && (port_pcs_dev_id[1] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) { hw_p->niu_type = NEPTUNE_2_TN1010_2_1GC; } else { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 3")); goto error_exit; } break; default: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 5")); goto error_exit; } break; case 1: /* Only one clause45 port */ switch (total_phy_fd) { /* Number of clause22 ports */ case 3: /* * TODO 3 1G, 1 10G mode. * Differentiate between 1_1G_1_10G_2_1G and * 1_10G_3_1G */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 7")); goto error_exit; case 2: /* * TODO 2 1G, 1 10G mode. * Differentiate between 1_1G_1_10G_1_1G and * 1_10G_2_1G */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 8")); goto error_exit; case 1: /* * TODO 1 1G, 1 10G mode. * Differentiate between 1_1G_1_10G and * 1_10G_1_1G */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 9")); goto error_exit; case 0: /* N2 with 1 XAUI (fiber or copper) */ /* Fiber XAUI */ if (port_pcs_dev_id[0] == PHY_BCM8704_FAMILY || port_pma_pmd_dev_id[0] == PHY_BCM8704_FAMILY) { /* * Check the first phy port address against * the known phy start addresses to determine * the platform type. */ switch (port_fd_arr[0]) { case N2_CLAUSE45_PORT_ADDR_BASE: case (N2_CLAUSE45_PORT_ADDR_BASE + 1): case ALT_GOA_CLAUSE45_PORT1_ADDR: /* * If hw_p->platform_type == * P_NEPTUNE_NIU, then portmode * is already known, so there is * no need to figure out hw_p-> * platform_type because * platform_type is only for * figuring out portmode. */ if (hw_p->platform_type != P_NEPTUNE_NIU) { hw_p->platform_type = P_NEPTUNE_GENERIC; hw_p->niu_type = NEPTUNE_2_10GF; } break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unsupported neptune type 10")); goto error_exit; } /* * For GOA, which is a hot swappable PHY, the * phy address to function number mapping * should be preserved, i.e., addr 16 is * assigned to function 0 and 20 to function 1 * But for Huron XAUI, the assignment should * be by function number, i.e., whichever * function number attaches should be * assigned the available PHY (this is required * primarily to support pre-production Huron * boards where function 0 is mapped to addr 17 */ if (port_fd_arr[0] == ALT_GOA_CLAUSE45_PORT1_ADDR) { hw_p->xcvr_addr[1] = port_fd_arr[0]; } else { hw_p->xcvr_addr[nxgep->function_num] = port_fd_arr[0]; } /* A 10G copper XAUI in either slot0 or slot1 */ } else if ((port_pcs_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID || (port_pma_pmd_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) { switch (port_fd_arr[0]) { /* The XAUI is in slot0 */ case N2_CLAUSE45_PORT_ADDR_BASE: hw_p->niu_type = NEPTUNE_1_TN1010; break; /* The XAUI is in slot1 */ case (N2_CLAUSE45_PORT_ADDR_BASE + 1): hw_p->niu_type = NEPTUNE_1_NONE_1_TN1010; break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unsupported XAUI port address")); goto error_exit; } hw_p->xcvr_addr[nxgep->function_num] = port_fd_arr[0]; } else { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported PHY type")); goto error_exit; } break; case 4: /* Maramba always have 4 clause 45 ports */ /* Maramba with 1 XAUI */ if ((port_pcs_dev_id[0] != PHY_BCM8704_FAMILY) && (port_pma_pmd_dev_id[0] != PHY_BCM8704_FAMILY) && ((port_pcs_dev_id[0] & TN1010_DEV_ID_MASK) != TN1010_DEV_ID) && ((port_pma_pmd_dev_id[0] & TN1010_DEV_ID_MASK) != TN1010_DEV_ID)) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 12")); goto error_exit; } /* * Check the first phy port address against * the known phy start addresses to determine * the platform type. */ switch (phy_fd_arr[0]) { case MARAMBA_P0_CLAUSE22_PORT_ADDR_BASE: hw_p->platform_type = P_NEPTUNE_MARAMBA_P0; break; case MARAMBA_P1_CLAUSE22_PORT_ADDR_BASE: hw_p->platform_type = P_NEPTUNE_MARAMBA_P1; break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unknown port %d...Cannot " "determine platform type 10 - 2", i)); goto error_exit; } /* * Check the clause45 address to determine * if XAUI is in port 0 or port 1. */ switch (port_fd_arr[0]) { case MARAMBA_CLAUSE45_PORT_ADDR_BASE: if (port_pcs_dev_id[0] == PHY_BCM8704_FAMILY || port_pma_pmd_dev_id[0] == PHY_BCM8704_FAMILY) { hw_p->niu_type = NEPTUNE_1_10GF_3_1GC; } else { hw_p->niu_type = NEPTUNE_1_TN1010_3_1GC; } hw_p->xcvr_addr[0] = port_fd_arr[0]; for (i = 1; i < NXGE_MAX_PORTS; i++) { hw_p->xcvr_addr[i] = phy_fd_arr[i]; } break; case (MARAMBA_CLAUSE45_PORT_ADDR_BASE + 1): if (port_pcs_dev_id[0] == PHY_BCM8704_FAMILY || port_pma_pmd_dev_id[0] == PHY_BCM8704_FAMILY) { hw_p->niu_type = NEPTUNE_1_1GC_1_10GF_2_1GC; } else { hw_p->niu_type = NEPTUNE_1_1GC_1_TN1010_2_1GC; } hw_p->xcvr_addr[0] = phy_fd_arr[0]; hw_p->xcvr_addr[1] = port_fd_arr[0]; hw_p->xcvr_addr[2] = phy_fd_arr[2]; hw_p->xcvr_addr[3] = phy_fd_arr[3]; break; default: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 11")); goto error_exit; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Maramba with 1 XAUI (fiber or copper)")); break; default: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 13")); goto error_exit; } break; case 0: /* 4 ports Neptune based NIC */ switch (total_phy_fd) { case 4: if ((port_phy_id[0] == PHY_BCM5464R_FAMILY) && (port_phy_id[1] == PHY_BCM5464R_FAMILY) && (port_phy_id[2] == PHY_BCM5464R_FAMILY) && (port_phy_id[3] == PHY_BCM5464R_FAMILY)) { /* * Check the first phy port address against * the known phy start addresses to determine * the platform type. */ switch (phy_fd_arr[0]) { case MARAMBA_P1_CLAUSE22_PORT_ADDR_BASE: hw_p->platform_type = P_NEPTUNE_MARAMBA_P1; break; case NEPTUNE_CLAUSE22_PORT_ADDR_BASE: hw_p->platform_type = P_NEPTUNE_ATLAS_4PORT; break; default: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unknown port %d...Cannot " "determine platform type", i)); goto error_exit; } hw_p->niu_type = NEPTUNE_4_1GC; for (i = 0; i < NXGE_MAX_PORTS; i++) { hw_p->xcvr_addr[i] = phy_fd_arr[i]; } } else { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 14")); goto error_exit; } break; case 3: /* TODO 3 1G mode */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 15")); goto error_exit; case 2: /* TODO 2 1G mode */ if ((port_phy_id[0] == PHY_BCM5482_FAMILY) && (port_phy_id[1] == PHY_BCM5482_FAMILY)) { hw_p->platform_type = P_NEPTUNE_GENERIC; hw_p->niu_type = NEPTUNE_2_1GRF; hw_p->xcvr_addr[2] = phy_fd_arr[0]; hw_p->xcvr_addr[3] = phy_fd_arr[1]; } else { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Unsupported neptune type 16")); goto error_exit; } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "2 RGMII Fiber ports - RTM")); break; case 1: /* TODO 1 1G mode */ NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 17")); goto error_exit; default: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 18, total phy fd %d", total_phy_fd)); goto error_exit; } break; default: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "Unsupported neptune type 19")); goto error_exit; } scan_exit: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_scan_ports_phy, " "niu type [0x%x]\n", hw_p->niu_type)); return (status); error_exit: return (NXGE_ERROR); } boolean_t nxge_is_valid_local_mac(ether_addr_st mac_addr) { if ((mac_addr.ether_addr_octet[0] & 0x01) || (ether_cmp(&mac_addr, ðerbroadcastaddr) == 0) || (ether_cmp(&mac_addr, ðerzeroaddr) == 0)) return (B_FALSE); else return (B_TRUE); } static void nxge_bcm5464_link_led_off(p_nxge_t nxgep) { npi_status_t rs = NPI_SUCCESS; uint8_t xcvr_portn; uint8_t portn = NXGE_GET_PORT_NUM(nxgep->function_num); NXGE_DEBUG_MSG((nxgep, MIF_CTL, "==> nxge_bcm5464_link_led_off")); if (nxgep->nxge_hw_p->platform_type == P_NEPTUNE_MARAMBA_P1) { xcvr_portn = MARAMBA_P1_CLAUSE22_PORT_ADDR_BASE; } else if (nxgep->nxge_hw_p->platform_type == P_NEPTUNE_MARAMBA_P0) { xcvr_portn = MARAMBA_P0_CLAUSE22_PORT_ADDR_BASE; } /* * For Altas 4-1G copper, Xcvr port numbers are * swapped with ethernet port number. This is * designed for better signal integrity in routing. */ switch (portn) { case 0: xcvr_portn += 3; break; case 1: xcvr_portn += 2; break; case 2: xcvr_portn += 1; break; case 3: default: break; } MUTEX_ENTER(&nxgep->nxge_hw_p->nxge_mdio_lock); rs = npi_mac_mif_mii_write(nxgep->npi_handle, xcvr_portn, BCM5464R_MISC, 0xb4ee); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_bcm5464_link_led_off: npi_mac_mif_mii_write " "returned error 0x[%x]", rs)); MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); return; } rs = npi_mac_mif_mii_write(nxgep->npi_handle, xcvr_portn, BCM5464R_MISC, 0xb8ee); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_bcm5464_link_led_off: npi_mac_mif_mii_write " "returned error 0x[%x]", rs)); } MUTEX_EXIT(&nxgep->nxge_hw_p->nxge_mdio_lock); } static nxge_status_t nxge_mii_get_link_mode(p_nxge_t nxgep) { p_nxge_stats_t statsp; uint8_t xcvr_portn; p_mii_regs_t mii_regs; mii_mode_control_stat_t mode; int status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mii_get_link_mode")); statsp = nxgep->statsp; xcvr_portn = statsp->mac_stats.xcvr_portn; mii_regs = NULL; mode.value = 0; mode.bits.shadow = NXGE_MII_MODE_CONTROL_REG; #if defined(__i386) if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->shadow), mode.value)) != NXGE_OK) { goto fail; #else if ((status = nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->shadow), mode.value)) != NXGE_OK) { goto fail; #endif } #if defined(__i386) if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->shadow), &mode.value)) != NXGE_OK) { goto fail; } #else if ((status = nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->shadow), &mode.value)) != NXGE_OK) { goto fail; } #endif if (mode.bits.mode == NXGE_MODE_SELECT_FIBER) { nxgep->mac.portmode = PORT_1G_RGMII_FIBER; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_mii_get_link_mode: fiber mode")); } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_mii_get_link_mode: " "(address 0x%x) port 0x%x mode value 0x%x link mode 0x%x", NXGE_MII_MODE_CONTROL_REG, xcvr_portn, mode.value, nxgep->mac.portmode)); NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_mii_get_link_mode")); return (status); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_mii_get_link_mode (failed)")); return (NXGE_ERROR); } nxge_status_t nxge_mac_set_framesize(p_nxge_t nxgep) { npi_attr_t ap; uint8_t portn; npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mac_set_framesize")); portn = NXGE_GET_PORT_NUM(nxgep->function_num); handle = nxgep->npi_handle; NXGE_DEBUG_MSG((nxgep, MAC_CTL, "==> nxge_mac_sec_framesize: port<%d> " "min framesize %d max framesize %d ", portn, nxgep->mac.minframesize, nxgep->mac.maxframesize)); SET_MAC_ATTR2(handle, ap, portn, MAC_PORT_FRAME_SIZE, nxgep->mac.minframesize, nxgep->mac.maxframesize, rs); if (rs != NPI_SUCCESS) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_mac_set_framesize: failed to configure " "max/min frame size port %d", portn)); return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, MAC_CTL, "<== nxge_mac_set_framesize: port<%d>", portn)); return (NXGE_OK); } static nxge_status_t nxge_get_num_of_xaui(uint32_t *port_pma_pmd_dev_id, uint32_t *port_pcs_dev_id, uint32_t *port_phy_id, uint8_t *num_xaui) { uint8_t i; for (i = 0; i < 4; i++) { if (port_phy_id[i] != PHY_BCM5464R_FAMILY) return (NXGE_ERROR); } *num_xaui = 0; if ((port_pma_pmd_dev_id[0] == PHY_BCM8704_FAMILY && port_pcs_dev_id[0] == PHY_BCM8704_FAMILY) || (((port_pma_pmd_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) && ((port_pcs_dev_id[0] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID))) { (*num_xaui) ++; } if ((port_pma_pmd_dev_id[1] == PHY_BCM8704_FAMILY && port_pcs_dev_id[1] == PHY_BCM8704_FAMILY) || (((port_pma_pmd_dev_id[1] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID) && ((port_pcs_dev_id[1] & TN1010_DEV_ID_MASK) == TN1010_DEV_ID))) { (*num_xaui) ++; } return (NXGE_OK); } /* * Instruction from Teranetics: Once you detect link is up, go * read Reg 30.1.4 for link speed: '1' for 1G and '0' for 10G. You * may want to qualify it by first checking Register 30.1.7:6 and * making sure it reads "01" (Auto-Neg Complete). * * If this function is called when the link is down or before auto- * negotiation has completed, then the speed of the PHY is not certain. * In such cases, this function returns 1G as the default speed with * NXGE_OK status instead of NXGE_ERROR. It is OK to initialize the * driver based on a default speed because this function will be called * again when the link comes up. Returning NXGE_ERROR, which may * cause brutal chain reaction in caller functions, is not necessary. */ static nxge_status_t nxge_get_tn1010_speed(p_nxge_t nxgep, uint16_t *speed) { uint8_t phy_port_addr, autoneg_stat, link_up; nxge_status_t status = NXGE_OK; uint16_t val; uint8_t portn = NXGE_GET_PORT_NUM(nxgep->function_num); /* Set default speed to 10G */ *speed = TN1010_SPEED_10G; /* Set Clause 45 */ npi_mac_mif_set_indirect_mode(nxgep->npi_handle, B_TRUE); phy_port_addr = nxgep->nxge_hw_p->xcvr_addr[portn]; /* Check Device 1 Register 0xA bit0 for link up status */ status = nxge_mdio_read(nxgep, phy_port_addr, TN1010_AUTONEG_DEV_ADDR, TN1010_AUTONEG_STATUS_REG, &val); if (status != NXGE_OK) goto fail; link_up = ((val & TN1010_AN_LINK_STAT_BIT) ? B_TRUE : B_FALSE); if (link_up == B_FALSE) { NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_get_tn1010_speed: link is down")); goto nxge_get_tn1010_speed_exit; } if ((status = nxge_mdio_read(nxgep, phy_port_addr, TN1010_VENDOR_MMD1_DEV_ADDR, TN1010_VENDOR_MMD1_STATUS_REG, &val)) != NXGE_OK) { goto fail; } autoneg_stat = (val & TN1010_VENDOR_MMD1_AN_STAT_BITS) >> TN1010_VENDOR_MMD1_AN_STAT_SHIFT; /* * Return NXGE_OK even when we can not get a settled speed. In * such case, the speed reported should not be trusted but that * is OK, we will call this function periodically and will get * the correct speed after the link is up. */ switch (autoneg_stat) { case TN1010_AN_IN_PROG: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_get_tn1010_speed: Auto-negotiation in progress")); break; case TN1010_AN_COMPLETE: if ((status = nxge_mdio_read(nxgep, phy_port_addr, TN1010_VENDOR_MMD1_DEV_ADDR, TN1010_VENDOR_MMD1_STATUS_REG, &val)) != NXGE_OK) { goto fail; } *speed = (val & TN1010_VENDOR_MMD1_AN_SPEED_BIT) >> TN1010_VENDOR_MMD1_AN_SPEED_SHIFT; break; case TN1010_AN_RSVD: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_get_tn1010_speed: Autoneg status undefined")); break; case TN1010_AN_FAILED: NXGE_DEBUG_MSG((nxgep, MAC_CTL, "nxge_get_tn1010_speed: Auto-negotiation failed")); break; default: break; } nxge_get_tn1010_speed_exit: return (NXGE_OK); fail: return (status); } /* * Teranetics TN1010 PHY chip supports both 1G and 10G modes, this function * figures out the speed of the PHY determined by the autonegotiation * process and sets the following 3 parameters, * nxgep->mac.portmode * nxgep->statsp->mac_stats.link_speed * nxgep->statsp->mac_stats.xcvr_inuse */ static nxge_status_t nxge_set_tn1010_param(p_nxge_t nxgep) { uint16_t speed; if (nxge_get_tn1010_speed(nxgep, &speed) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_set_tn1010_param: " "Failed to get TN1010 speed")); return (NXGE_ERROR); } if (speed == TN1010_SPEED_1G) { nxgep->mac.portmode = PORT_1G_TN1010; nxgep->statsp->mac_stats.link_speed = 1000; nxgep->statsp->mac_stats.xcvr_inuse = PCS_XCVR; } else { nxgep->mac.portmode = PORT_10G_TN1010; nxgep->statsp->mac_stats.link_speed = 10000; nxgep->statsp->mac_stats.xcvr_inuse = XPCS_XCVR; } return (NXGE_OK); } #ifdef NXGE_DEBUG static void nxge_mii_dump(p_nxge_t nxgep) { p_nxge_stats_t statsp; uint8_t xcvr_portn; p_mii_regs_t mii_regs; mii_bmcr_t bmcr; mii_bmsr_t bmsr; mii_idr1_t idr1; mii_idr2_t idr2; mii_mode_control_stat_t mode; p_nxge_param_t param_arr; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_mii_dump")); statsp = nxgep->statsp; xcvr_portn = statsp->mac_stats.xcvr_portn; mii_regs = NULL; #if defined(__i386) (void) nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmcr), &bmcr.value); #else (void) nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmcr), &bmcr.value); #endif NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mii_dump: bmcr (0) xcvr 0x%x value 0x%x", xcvr_portn, bmcr.value)); #if defined(__i386) (void) nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->bmsr), &bmsr.value); #else (void) nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->bmsr), &bmsr.value); #endif NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mii_dump: bmsr (1) xcvr 0x%x value 0x%x", xcvr_portn, bmsr.value)); #if defined(__i386) (void) nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->idr1), &idr1.value); #else (void) nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->idr1), &idr1.value); #endif #if defined(__i386) (void) nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->idr2), &idr2.value); #else (void) nxge_mii_read(nxgep, nxgep->statsp->mac_stats.xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->idr2), &idr2.value); #endif NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mii_dump: idr1 (2) xcvr 0x%x value 0x%x", xcvr_portn, idr1.value)); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mii_dump: idr2 (3) xcvr 0x%x value 0x%x", xcvr_portn, idr2.value)); mode.value = 0; mode.bits.shadow = NXGE_MII_MODE_CONTROL_REG; #if defined(__i386) (void) nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->shadow), mode.value); (void) nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint32_t)(&mii_regs->shadow), &mode.value); #else (void) nxge_mii_write(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->shadow), mode.value); (void) nxge_mii_read(nxgep, xcvr_portn, (uint8_t)(uint64_t)(&mii_regs->shadow), &mode.value); #endif NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_mii_dump: mode control xcvr 0x%x value 0x%x", xcvr_portn, mode.value)); } #endif