/* * Agere Systems Inc. * 10/100/1000 Base-T Ethernet Driver for the ET1301 and ET131x series MACs * * Copyright © 2005 Agere Systems Inc. * All rights reserved. * http://www.agere.com * *------------------------------------------------------------------------------ * * et1310_phy.h - Defines, structs, enums, prototypes, etc. pertaining to the * PHY. * *------------------------------------------------------------------------------ * * SOFTWARE LICENSE * * This software is provided subject to the following terms and conditions, * which you should read carefully before using the software. Using this * software indicates your acceptance of these terms and conditions. If you do * not agree with these terms and conditions, do not use the software. * * Copyright © 2005 Agere Systems Inc. * All rights reserved. * * Redistribution and use in source or binary forms, with or without * modifications, are permitted provided that the following conditions are met: * * . Redistributions of source code must retain the above copyright notice, this * list of conditions and the following Disclaimer as comments in the code as * well as in the documentation and/or other materials provided with the * distribution. * * . Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following Disclaimer in the documentation * and/or other materials provided with the distribution. * * . Neither the name of Agere Systems Inc. nor the names of the contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * Disclaimer * * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, * INCLUDING, BUT NOT LIMITED TO, INFRINGEMENT AND THE IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. ANY * USE, MODIFICATION OR DISTRIBUTION OF THIS SOFTWARE IS SOLELY AT THE USERS OWN * RISK. IN NO EVENT SHALL AGERE SYSTEMS INC. OR CONTRIBUTORS BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, INCLUDING, BUT NOT LIMITED TO, CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH * DAMAGE. * */ #ifndef _ET1310_PHY_H_ #define _ET1310_PHY_H_ #include "et1310_address_map.h" /* MI Register Addresses */ #define MI_CONTROL_REG 0 #define MI_STATUS_REG 1 #define MI_PHY_IDENTIFIER_1_REG 2 #define MI_PHY_IDENTIFIER_2_REG 3 #define MI_AUTONEG_ADVERTISEMENT_REG 4 #define MI_AUTONEG_LINK_PARTNER_ABILITY_REG 5 #define MI_AUTONEG_EXPANSION_REG 6 #define MI_AUTONEG_NEXT_PAGE_TRANSMIT_REG 7 #define MI_LINK_PARTNER_NEXT_PAGE_REG 8 #define MI_1000BASET_CONTROL_REG 9 #define MI_1000BASET_STATUS_REG 10 #define MI_RESERVED11_REG 11 #define MI_RESERVED12_REG 12 #define MI_RESERVED13_REG 13 #define MI_RESERVED14_REG 14 #define MI_EXTENDED_STATUS_REG 15 /* VMI Register Addresses */ #define VMI_RESERVED16_REG 16 #define VMI_RESERVED17_REG 17 #define VMI_RESERVED18_REG 18 #define VMI_LOOPBACK_CONTROL_REG 19 #define VMI_RESERVED20_REG 20 #define VMI_MI_CONTROL_REG 21 #define VMI_PHY_CONFIGURATION_REG 22 #define VMI_PHY_CONTROL_REG 23 #define VMI_INTERRUPT_MASK_REG 24 #define VMI_INTERRUPT_STATUS_REG 25 #define VMI_PHY_STATUS_REG 26 #define VMI_LED_CONTROL_1_REG 27 #define VMI_LED_CONTROL_2_REG 28 #define VMI_RESERVED29_REG 29 #define VMI_RESERVED30_REG 30 #define VMI_RESERVED31_REG 31 /* PHY Register Mapping(MI) Management Interface Regs */ typedef struct _MI_REGS_t { u8 bmcr; /* Basic mode control reg(Reg 0x00) */ u8 bmsr; /* Basic mode status reg(Reg 0x01) */ u8 idr1; /* Phy identifier reg 1(Reg 0x02) */ u8 idr2; /* Phy identifier reg 2(Reg 0x03) */ u8 anar; /* Auto-Negotiation advertisement(Reg 0x04) */ u8 anlpar; /* Auto-Negotiation link Partner Ability(Reg 0x05) */ u8 aner; /* Auto-Negotiation expansion reg(Reg 0x06) */ u8 annptr; /* Auto-Negotiation next page transmit reg(Reg 0x07) */ u8 lpnpr; /* link partner next page reg(Reg 0x08) */ u8 gcr; /* Gigabit basic mode control reg(Reg 0x09) */ u8 gsr; /* Gigabit basic mode status reg(Reg 0x0A) */ u8 mi_res1[4]; /* Future use by MI working group(Reg 0x0B - 0x0E) */ u8 esr; /* Extended status reg(Reg 0x0F) */ u8 mi_res2[3]; /* Future use by MI working group(Reg 0x10 - 0x12) */ u8 loop_ctl; /* Loopback Control Reg(Reg 0x13) */ u8 mi_res3; /* Future use by MI working group(Reg 0x14) */ u8 mcr; /* MI Control Reg(Reg 0x15) */ u8 pcr; /* Configuration Reg(Reg 0x16) */ u8 phy_ctl; /* PHY Control Reg(Reg 0x17) */ u8 imr; /* Interrupt Mask Reg(Reg 0x18) */ u8 isr; /* Interrupt Status Reg(Reg 0x19) */ u8 psr; /* PHY Status Reg(Reg 0x1A) */ u8 lcr1; /* LED Control 1 Reg(Reg 0x1B) */ u8 lcr2; /* LED Control 2 Reg(Reg 0x1C) */ u8 mi_res4[3]; /* Future use by MI working group(Reg 0x1D - 0x1F) */ } MI_REGS_t, *PMI_REGS_t; /* MI Register 0: Basic mode control register */ typedef union _MI_BMCR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 reset:1; /* bit 15 */ u16 loopback:1; /* bit 14 */ u16 speed_sel:1; /* bit 13 */ u16 enable_autoneg:1; /* bit 12 */ u16 power_down:1; /* bit 11 */ u16 isolate:1; /* bit 10 */ u16 restart_autoneg:1; /* bit 9 */ u16 duplex_mode:1; /* bit 8 */ u16 col_test:1; /* bit 7 */ u16 speed_1000_sel:1; /* bit 6 */ u16 res1:6; /* bits 0-5 */ #else u16 res1:6; /* bits 0-5 */ u16 speed_1000_sel:1; /* bit 6 */ u16 col_test:1; /* bit 7 */ u16 duplex_mode:1; /* bit 8 */ u16 restart_autoneg:1; /* bit 9 */ u16 isolate:1; /* bit 10 */ u16 power_down:1; /* bit 11 */ u16 enable_autoneg:1; /* bit 12 */ u16 speed_sel:1; /* bit 13 */ u16 loopback:1; /* bit 14 */ u16 reset:1; /* bit 15 */ #endif } bits; } MI_BMCR_t, *PMI_BMCR_t; /* MI Register 1: Basic mode status register */ typedef union _MI_BMSR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 link_100T4:1; /* bit 15 */ u16 link_100fdx:1; /* bit 14 */ u16 link_100hdx:1; /* bit 13 */ u16 link_10fdx:1; /* bit 12 */ u16 link_10hdx:1; /* bit 11 */ u16 link_100T2fdx:1; /* bit 10 */ u16 link_100T2hdx:1; /* bit 9 */ u16 extend_status:1; /* bit 8 */ u16 res1:1; /* bit 7 */ u16 preamble_supress:1; /* bit 6 */ u16 auto_neg_complete:1; /* bit 5 */ u16 remote_fault:1; /* bit 4 */ u16 auto_neg_able:1; /* bit 3 */ u16 link_status:1; /* bit 2 */ u16 jabber_detect:1; /* bit 1 */ u16 ext_cap:1; /* bit 0 */ #else u16 ext_cap:1; /* bit 0 */ u16 jabber_detect:1; /* bit 1 */ u16 link_status:1; /* bit 2 */ u16 auto_neg_able:1; /* bit 3 */ u16 remote_fault:1; /* bit 4 */ u16 auto_neg_complete:1; /* bit 5 */ u16 preamble_supress:1; /* bit 6 */ u16 res1:1; /* bit 7 */ u16 extend_status:1; /* bit 8 */ u16 link_100T2hdx:1; /* bit 9 */ u16 link_100T2fdx:1; /* bit 10 */ u16 link_10hdx:1; /* bit 11 */ u16 link_10fdx:1; /* bit 12 */ u16 link_100hdx:1; /* bit 13 */ u16 link_100fdx:1; /* bit 14 */ u16 link_100T4:1; /* bit 15 */ #endif } bits; } MI_BMSR_t, *PMI_BMSR_t; /* MI Register 2: Physical Identifier 1 */ typedef union _MI_IDR1_t { u16 value; struct { u16 ieee_address:16; /* 0x0282 default(bits 0-15) */ } bits; } MI_IDR1_t, *PMI_IDR1_t; /* MI Register 3: Physical Identifier 2 */ typedef union _MI_IDR2_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 ieee_address:6; /* 111100 default(bits 10-15) */ u16 model_no:6; /* 000001 default(bits 4-9) */ u16 rev_no:4; /* 0010 default(bits 0-3) */ #else u16 rev_no:4; /* 0010 default(bits 0-3) */ u16 model_no:6; /* 000001 default(bits 4-9) */ u16 ieee_address:6; /* 111100 default(bits 10-15) */ #endif } bits; } MI_IDR2_t, *PMI_IDR2_t; /* MI Register 4: Auto-negotiation advertisement register */ typedef union _MI_ANAR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 np_indication:1; /* bit 15 */ u16 res2:1; /* bit 14 */ u16 remote_fault:1; /* bit 13 */ u16 res1:1; /* bit 12 */ u16 cap_asmpause:1; /* bit 11 */ u16 cap_pause:1; /* bit 10 */ u16 cap_100T4:1; /* bit 9 */ u16 cap_100fdx:1; /* bit 8 */ u16 cap_100hdx:1; /* bit 7 */ u16 cap_10fdx:1; /* bit 6 */ u16 cap_10hdx:1; /* bit 5 */ u16 selector:5; /* bits 0-4 */ #else u16 selector:5; /* bits 0-4 */ u16 cap_10hdx:1; /* bit 5 */ u16 cap_10fdx:1; /* bit 6 */ u16 cap_100hdx:1; /* bit 7 */ u16 cap_100fdx:1; /* bit 8 */ u16 cap_100T4:1; /* bit 9 */ u16 cap_pause:1; /* bit 10 */ u16 cap_asmpause:1; /* bit 11 */ u16 res1:1; /* bit 12 */ u16 remote_fault:1; /* bit 13 */ u16 res2:1; /* bit 14 */ u16 np_indication:1; /* bit 15 */ #endif } bits; } MI_ANAR_t, *PMI_ANAR_t; /* MI Register 5: Auto-negotiation link partner advertisement register */ typedef struct _MI_ANLPAR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 np_indication:1; /* bit 15 */ u16 acknowledge:1; /* bit 14 */ u16 remote_fault:1; /* bit 13 */ u16 res1:1; /* bit 12 */ u16 cap_asmpause:1; /* bit 11 */ u16 cap_pause:1; /* bit 10 */ u16 cap_100T4:1; /* bit 9 */ u16 cap_100fdx:1; /* bit 8 */ u16 cap_100hdx:1; /* bit 7 */ u16 cap_10fdx:1; /* bit 6 */ u16 cap_10hdx:1; /* bit 5 */ u16 selector:5; /* bits 0-4 */ #else u16 selector:5; /* bits 0-4 */ u16 cap_10hdx:1; /* bit 5 */ u16 cap_10fdx:1; /* bit 6 */ u16 cap_100hdx:1; /* bit 7 */ u16 cap_100fdx:1; /* bit 8 */ u16 cap_100T4:1; /* bit 9 */ u16 cap_pause:1; /* bit 10 */ u16 cap_asmpause:1; /* bit 11 */ u16 res1:1; /* bit 12 */ u16 remote_fault:1; /* bit 13 */ u16 acknowledge:1; /* bit 14 */ u16 np_indication:1; /* bit 15 */ #endif } bits; } MI_ANLPAR_t, *PMI_ANLPAR_t; /* MI Register 6: Auto-negotiation expansion register */ typedef union _MI_ANER_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 res:11; /* bits 5-15 */ u16 pdf:1; /* bit 4 */ u16 lp_np_able:1; /* bit 3 */ u16 np_able:1; /* bit 2 */ u16 page_rx:1; /* bit 1 */ u16 lp_an_able:1; /* bit 0 */ #else u16 lp_an_able:1; /* bit 0 */ u16 page_rx:1; /* bit 1 */ u16 np_able:1; /* bit 2 */ u16 lp_np_able:1; /* bit 3 */ u16 pdf:1; /* bit 4 */ u16 res:11; /* bits 5-15 */ #endif } bits; } MI_ANER_t, *PMI_ANER_t; /* MI Register 7: Auto-negotiation next page transmit reg(0x07) */ typedef union _MI_ANNPTR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 np:1; /* bit 15 */ u16 res1:1; /* bit 14 */ u16 msg_page:1; /* bit 13 */ u16 ack2:1; /* bit 12 */ u16 toggle:1; /* bit 11 */ u16 msg:11; /* bits 0-10 */ #else u16 msg:11; /* bits 0-10 */ u16 toggle:1; /* bit 11 */ u16 ack2:1; /* bit 12 */ u16 msg_page:1; /* bit 13 */ u16 res1:1; /* bit 14 */ u16 np:1; /* bit 15 */ #endif } bits; } MI_ANNPTR_t, *PMI_ANNPTR_t; /* MI Register 8: Link Partner Next Page Reg(0x08) */ typedef union _MI_LPNPR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 np:1; /* bit 15 */ u16 ack:1; /* bit 14 */ u16 msg_page:1; /* bit 13 */ u16 ack2:1; /* bit 12 */ u16 toggle:1; /* bit 11 */ u16 msg:11; /* bits 0-10 */ #else u16 msg:11; /* bits 0-10 */ u16 toggle:1; /* bit 11 */ u16 ack2:1; /* bit 12 */ u16 msg_page:1; /* bit 13 */ u16 ack:1; /* bit 14 */ u16 np:1; /* bit 15 */ #endif } bits; } MI_LPNPR_t, *PMI_LPNPR_t; /* MI Register 9: 1000BaseT Control Reg(0x09) */ typedef union _MI_GCR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 test_mode:3; /* bits 13-15 */ u16 ms_config_en:1; /* bit 12 */ u16 ms_value:1; /* bit 11 */ u16 port_type:1; /* bit 10 */ u16 link_1000fdx:1; /* bit 9 */ u16 link_1000hdx:1; /* bit 8 */ u16 res:8; /* bit 0-7 */ #else u16 res:8; /* bit 0-7 */ u16 link_1000hdx:1; /* bit 8 */ u16 link_1000fdx:1; /* bit 9 */ u16 port_type:1; /* bit 10 */ u16 ms_value:1; /* bit 11 */ u16 ms_config_en:1; /* bit 12 */ u16 test_mode:3; /* bits 13-15 */ #endif } bits; } MI_GCR_t, *PMI_GCR_t; /* MI Register 10: 1000BaseT Status Reg(0x0A) */ typedef union _MI_GSR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 ms_config_fault:1; /* bit 15 */ u16 ms_resolve:1; /* bit 14 */ u16 local_rx_status:1; /* bit 13 */ u16 remote_rx_status:1; /* bit 12 */ u16 link_1000fdx:1; /* bit 11 */ u16 link_1000hdx:1; /* bit 10 */ u16 res:2; /* bits 8-9 */ u16 idle_err_cnt:8; /* bits 0-7 */ #else u16 idle_err_cnt:8; /* bits 0-7 */ u16 res:2; /* bits 8-9 */ u16 link_1000hdx:1; /* bit 10 */ u16 link_1000fdx:1; /* bit 11 */ u16 remote_rx_status:1; /* bit 12 */ u16 local_rx_status:1; /* bit 13 */ u16 ms_resolve:1; /* bit 14 */ u16 ms_config_fault:1; /* bit 15 */ #endif } bits; } MI_GSR_t, *PMI_GSR_t; /* MI Register 11 - 14: Reserved Regs(0x0B - 0x0E) */ typedef union _MI_RES_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 res15:1; /* bit 15 */ u16 res14:1; /* bit 14 */ u16 res13:1; /* bit 13 */ u16 res12:1; /* bit 12 */ u16 res11:1; /* bit 11 */ u16 res10:1; /* bit 10 */ u16 res9:1; /* bit 9 */ u16 res8:1; /* bit 8 */ u16 res7:1; /* bit 7 */ u16 res6:1; /* bit 6 */ u16 res5:1; /* bit 5 */ u16 res4:1; /* bit 4 */ u16 res3:1; /* bit 3 */ u16 res2:1; /* bit 2 */ u16 res1:1; /* bit 1 */ u16 res0:1; /* bit 0 */ #else u16 res0:1; /* bit 0 */ u16 res1:1; /* bit 1 */ u16 res2:1; /* bit 2 */ u16 res3:1; /* bit 3 */ u16 res4:1; /* bit 4 */ u16 res5:1; /* bit 5 */ u16 res6:1; /* bit 6 */ u16 res7:1; /* bit 7 */ u16 res8:1; /* bit 8 */ u16 res9:1; /* bit 9 */ u16 res10:1; /* bit 10 */ u16 res11:1; /* bit 11 */ u16 res12:1; /* bit 12 */ u16 res13:1; /* bit 13 */ u16 res14:1; /* bit 14 */ u16 res15:1; /* bit 15 */ #endif } bits; } MI_RES_t, *PMI_RES_t; /* MI Register 15: Extended status Reg(0x0F) */ typedef union _MI_ESR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 link_1000Xfdx:1; /* bit 15 */ u16 link_1000Xhdx:1; /* bit 14 */ u16 link_1000fdx:1; /* bit 13 */ u16 link_1000hdx:1; /* bit 12 */ u16 res:12; /* bit 0-11 */ #else u16 res:12; /* bit 0-11 */ u16 link_1000hdx:1; /* bit 12 */ u16 link_1000fdx:1; /* bit 13 */ u16 link_1000Xhdx:1; /* bit 14 */ u16 link_1000Xfdx:1; /* bit 15 */ #endif } bits; } MI_ESR_t, *PMI_ESR_t; /* MI Register 16 - 18: Reserved Reg(0x10-0x12) */ /* MI Register 19: Loopback Control Reg(0x13) */ typedef union _MI_LCR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 mii_en:1; /* bit 15 */ u16 pcs_en:1; /* bit 14 */ u16 pmd_en:1; /* bit 13 */ u16 all_digital_en:1; /* bit 12 */ u16 replica_en:1; /* bit 11 */ u16 line_driver_en:1; /* bit 10 */ u16 res:10; /* bit 0-9 */ #else u16 res:10; /* bit 0-9 */ u16 line_driver_en:1; /* bit 10 */ u16 replica_en:1; /* bit 11 */ u16 all_digital_en:1; /* bit 12 */ u16 pmd_en:1; /* bit 13 */ u16 pcs_en:1; /* bit 14 */ u16 mii_en:1; /* bit 15 */ #endif } bits; } MI_LCR_t, *PMI_LCR_t; /* MI Register 20: Reserved Reg(0x14) */ /* MI Register 21: Management Interface Control Reg(0x15) */ typedef union _MI_MICR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 res1:5; /* bits 11-15 */ u16 mi_error_count:7; /* bits 4-10 */ u16 res2:1; /* bit 3 */ u16 ignore_10g_fr:1; /* bit 2 */ u16 res3:1; /* bit 1 */ u16 preamble_supress_en:1; /* bit 0 */ #else u16 preamble_supress_en:1; /* bit 0 */ u16 res3:1; /* bit 1 */ u16 ignore_10g_fr:1; /* bit 2 */ u16 res2:1; /* bit 3 */ u16 mi_error_count:7; /* bits 4-10 */ u16 res1:5; /* bits 11-15 */ #endif } bits; } MI_MICR_t, *PMI_MICR_t; /* MI Register 22: PHY Configuration Reg(0x16) */ typedef union _MI_PHY_CONFIG_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 crs_tx_en:1; /* bit 15 */ u16 res1:1; /* bit 14 */ u16 tx_fifo_depth:2; /* bits 12-13 */ u16 speed_downshift:2; /* bits 10-11 */ u16 pbi_detect:1; /* bit 9 */ u16 tbi_rate:1; /* bit 8 */ u16 alternate_np:1; /* bit 7 */ u16 group_mdio_en:1; /* bit 6 */ u16 tx_clock_en:1; /* bit 5 */ u16 sys_clock_en:1; /* bit 4 */ u16 res2:1; /* bit 3 */ u16 mac_if_mode:3; /* bits 0-2 */ #else u16 mac_if_mode:3; /* bits 0-2 */ u16 res2:1; /* bit 3 */ u16 sys_clock_en:1; /* bit 4 */ u16 tx_clock_en:1; /* bit 5 */ u16 group_mdio_en:1; /* bit 6 */ u16 alternate_np:1; /* bit 7 */ u16 tbi_rate:1; /* bit 8 */ u16 pbi_detect:1; /* bit 9 */ u16 speed_downshift:2; /* bits 10-11 */ u16 tx_fifo_depth:2; /* bits 12-13 */ u16 res1:1; /* bit 14 */ u16 crs_tx_en:1; /* bit 15 */ #endif } bits; } MI_PHY_CONFIG_t, *PMI_PHY_CONFIG_t; /* MI Register 23: PHY CONTROL Reg(0x17) */ typedef union _MI_PHY_CONTROL_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 res1:1; /* bit 15 */ u16 tdr_en:1; /* bit 14 */ u16 res2:1; /* bit 13 */ u16 downshift_attempts:2; /* bits 11-12 */ u16 res3:5; /* bit 6-10 */ u16 jabber_10baseT:1; /* bit 5 */ u16 sqe_10baseT:1; /* bit 4 */ u16 tp_loopback_10baseT:1; /* bit 3 */ u16 preamble_gen_en:1; /* bit 2 */ u16 res4:1; /* bit 1 */ u16 force_int:1; /* bit 0 */ #else u16 force_int:1; /* bit 0 */ u16 res4:1; /* bit 1 */ u16 preamble_gen_en:1; /* bit 2 */ u16 tp_loopback_10baseT:1; /* bit 3 */ u16 sqe_10baseT:1; /* bit 4 */ u16 jabber_10baseT:1; /* bit 5 */ u16 res3:5; /* bit 6-10 */ u16 downshift_attempts:2; /* bits 11-12 */ u16 res2:1; /* bit 13 */ u16 tdr_en:1; /* bit 14 */ u16 res1:1; /* bit 15 */ #endif } bits; } MI_PHY_CONTROL_t, *PMI_PHY_CONTROL_t; /* MI Register 24: Interrupt Mask Reg(0x18) */ typedef union _MI_IMR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 res1:6; /* bits 10-15 */ u16 mdio_sync_lost:1; /* bit 9 */ u16 autoneg_status:1; /* bit 8 */ u16 hi_bit_err:1; /* bit 7 */ u16 np_rx:1; /* bit 6 */ u16 err_counter_full:1; /* bit 5 */ u16 fifo_over_underflow:1; /* bit 4 */ u16 rx_status:1; /* bit 3 */ u16 link_status:1; /* bit 2 */ u16 automatic_speed:1; /* bit 1 */ u16 int_en:1; /* bit 0 */ #else u16 int_en:1; /* bit 0 */ u16 automatic_speed:1; /* bit 1 */ u16 link_status:1; /* bit 2 */ u16 rx_status:1; /* bit 3 */ u16 fifo_over_underflow:1; /* bit 4 */ u16 err_counter_full:1; /* bit 5 */ u16 np_rx:1; /* bit 6 */ u16 hi_bit_err:1; /* bit 7 */ u16 autoneg_status:1; /* bit 8 */ u16 mdio_sync_lost:1; /* bit 9 */ u16 res1:6; /* bits 10-15 */ #endif } bits; } MI_IMR_t, *PMI_IMR_t; /* MI Register 25: Interrupt Status Reg(0x19) */ typedef union _MI_ISR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 res1:6; /* bits 10-15 */ u16 mdio_sync_lost:1; /* bit 9 */ u16 autoneg_status:1; /* bit 8 */ u16 hi_bit_err:1; /* bit 7 */ u16 np_rx:1; /* bit 6 */ u16 err_counter_full:1; /* bit 5 */ u16 fifo_over_underflow:1; /* bit 4 */ u16 rx_status:1; /* bit 3 */ u16 link_status:1; /* bit 2 */ u16 automatic_speed:1; /* bit 1 */ u16 int_en:1; /* bit 0 */ #else u16 int_en:1; /* bit 0 */ u16 automatic_speed:1; /* bit 1 */ u16 link_status:1; /* bit 2 */ u16 rx_status:1; /* bit 3 */ u16 fifo_over_underflow:1; /* bit 4 */ u16 err_counter_full:1; /* bit 5 */ u16 np_rx:1; /* bit 6 */ u16 hi_bit_err:1; /* bit 7 */ u16 autoneg_status:1; /* bit 8 */ u16 mdio_sync_lost:1; /* bit 9 */ u16 res1:6; /* bits 10-15 */ #endif } bits; } MI_ISR_t, *PMI_ISR_t; /* MI Register 26: PHY Status Reg(0x1A) */ typedef union _MI_PSR_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 res1:1; /* bit 15 */ u16 autoneg_fault:2; /* bit 13-14 */ u16 autoneg_status:1; /* bit 12 */ u16 mdi_x_status:1; /* bit 11 */ u16 polarity_status:1; /* bit 10 */ u16 speed_status:2; /* bits 8-9 */ u16 duplex_status:1; /* bit 7 */ u16 link_status:1; /* bit 6 */ u16 tx_status:1; /* bit 5 */ u16 rx_status:1; /* bit 4 */ u16 collision_status:1; /* bit 3 */ u16 autoneg_en:1; /* bit 2 */ u16 pause_en:1; /* bit 1 */ u16 asymmetric_dir:1; /* bit 0 */ #else u16 asymmetric_dir:1; /* bit 0 */ u16 pause_en:1; /* bit 1 */ u16 autoneg_en:1; /* bit 2 */ u16 collision_status:1; /* bit 3 */ u16 rx_status:1; /* bit 4 */ u16 tx_status:1; /* bit 5 */ u16 link_status:1; /* bit 6 */ u16 duplex_status:1; /* bit 7 */ u16 speed_status:2; /* bits 8-9 */ u16 polarity_status:1; /* bit 10 */ u16 mdi_x_status:1; /* bit 11 */ u16 autoneg_status:1; /* bit 12 */ u16 autoneg_fault:2; /* bit 13-14 */ u16 res1:1; /* bit 15 */ #endif } bits; } MI_PSR_t, *PMI_PSR_t; /* MI Register 27: LED Control Reg 1(0x1B) */ typedef union _MI_LCR1_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 res1:2; /* bits 14-15 */ u16 led_dup_indicate:2; /* bits 12-13 */ u16 led_10baseT:2; /* bits 10-11 */ u16 led_collision:2; /* bits 8-9 */ u16 res2:2; /* bits 6-7 */ u16 res3:2; /* bits 4-5 */ u16 pulse_dur:2; /* bits 2-3 */ u16 pulse_stretch1:1; /* bit 1 */ u16 pulse_stretch0:1; /* bit 0 */ #else u16 pulse_stretch0:1; /* bit 0 */ u16 pulse_stretch1:1; /* bit 1 */ u16 pulse_dur:2; /* bits 2-3 */ u16 res3:2; /* bits 4-5 */ u16 res2:2; /* bits 6-7 */ u16 led_collision:2; /* bits 8-9 */ u16 led_10baseT:2; /* bits 10-11 */ u16 led_dup_indicate:2; /* bits 12-13 */ u16 res1:2; /* bits 14-15 */ #endif } bits; } MI_LCR1_t, *PMI_LCR1_t; /* MI Register 28: LED Control Reg 2(0x1C) */ typedef union _MI_LCR2_t { u16 value; struct { #ifdef _BIT_FIELDS_HTOL u16 led_link:4; /* bits 12-15 */ u16 led_tx_rx:4; /* bits 8-11 */ u16 led_100BaseTX:4; /* bits 4-7 */ u16 led_1000BaseT:4; /* bits 0-3 */ #else u16 led_1000BaseT:4; /* bits 0-3 */ u16 led_100BaseTX:4; /* bits 4-7 */ u16 led_tx_rx:4; /* bits 8-11 */ u16 led_link:4; /* bits 12-15 */ #endif } bits; } MI_LCR2_t, *PMI_LCR2_t; /* MI Register 29 - 31: Reserved Reg(0x1D - 0x1E) */ /* Prototypes for ET1310_phy.c */ /* Defines for PHY access routines */ /* Define bit operation flags */ #define TRUEPHY_BIT_CLEAR 0 #define TRUEPHY_BIT_SET 1 #define TRUEPHY_BIT_READ 2 /* Define read/write operation flags */ #ifndef TRUEPHY_READ #define TRUEPHY_READ 0 #define TRUEPHY_WRITE 1 #define TRUEPHY_MASK 2 #endif /* Define speeds */ #define TRUEPHY_SPEED_10MBPS 0 #define TRUEPHY_SPEED_100MBPS 1 #define TRUEPHY_SPEED_1000MBPS 2 /* Define duplex modes */ #define TRUEPHY_DUPLEX_HALF 0 #define TRUEPHY_DUPLEX_FULL 1 /* Define master/slave configuration values */ #define TRUEPHY_CFG_SLAVE 0 #define TRUEPHY_CFG_MASTER 1 /* Define MDI/MDI-X settings */ #define TRUEPHY_MDI 0 #define TRUEPHY_MDIX 1 #define TRUEPHY_AUTO_MDI_MDIX 2 /* Define 10Base-T link polarities */ #define TRUEPHY_POLARITY_NORMAL 0 #define TRUEPHY_POLARITY_INVERTED 1 /* Define auto-negotiation results */ #define TRUEPHY_ANEG_NOT_COMPLETE 0 #define TRUEPHY_ANEG_COMPLETE 1 #define TRUEPHY_ANEG_DISABLED 2 /* Define duplex advertisment flags */ #define TRUEPHY_ADV_DUPLEX_NONE 0x00 #define TRUEPHY_ADV_DUPLEX_FULL 0x01 #define TRUEPHY_ADV_DUPLEX_HALF 0x02 #define TRUEPHY_ADV_DUPLEX_BOTH \ (TRUEPHY_ADV_DUPLEX_FULL | TRUEPHY_ADV_DUPLEX_HALF) #define PHY_CONTROL 0x00 /* #define TRU_MI_CONTROL_REGISTER 0 */ #define PHY_STATUS 0x01 /* #define TRU_MI_STATUS_REGISTER 1 */ #define PHY_ID_1 0x02 /* #define TRU_MI_PHY_IDENTIFIER_1_REGISTER 2 */ #define PHY_ID_2 0x03 /* #define TRU_MI_PHY_IDENTIFIER_2_REGISTER 3 */ #define PHY_AUTO_ADVERTISEMENT 0x04 /* #define TRU_MI_ADVERTISEMENT_REGISTER 4 */ #define PHY_AUTO_LINK_PARTNER 0x05 /* #define TRU_MI_LINK_PARTNER_ABILITY_REGISTER 5 */ #define PHY_AUTO_EXPANSION 0x06 /* #define TRU_MI_EXPANSION_REGISTER 6 */ #define PHY_AUTO_NEXT_PAGE_TX 0x07 /* #define TRU_MI_NEXT_PAGE_TRANSMIT_REGISTER 7 */ #define PHY_LINK_PARTNER_NEXT_PAGE 0x08 /* #define TRU_MI_LINK_PARTNER_NEXT_PAGE_REGISTER 8 */ #define PHY_1000_CONTROL 0x09 /* #define TRU_MI_1000BASET_CONTROL_REGISTER 9 */ #define PHY_1000_STATUS 0x0A /* #define TRU_MI_1000BASET_STATUS_REGISTER 10 */ #define PHY_EXTENDED_STATUS 0x0F /* #define TRU_MI_EXTENDED_STATUS_REGISTER 15 */ /* some defines for modem registers that seem to be 'reserved' */ #define PHY_INDEX_REG 0x10 #define PHY_DATA_REG 0x11 #define PHY_MPHY_CONTROL_REG 0x12 /* #define TRU_VMI_MPHY_CONTROL_REGISTER 18 */ #define PHY_LOOPBACK_CONTROL 0x13 /* #define TRU_VMI_LOOPBACK_CONTROL_1_REGISTER 19 */ /* #define TRU_VMI_LOOPBACK_CONTROL_2_REGISTER 20 */ #define PHY_REGISTER_MGMT_CONTROL 0x15 /* #define TRU_VMI_MI_SEQ_CONTROL_REGISTER 21 */ #define PHY_CONFIG 0x16 /* #define TRU_VMI_CONFIGURATION_REGISTER 22 */ #define PHY_PHY_CONTROL 0x17 /* #define TRU_VMI_PHY_CONTROL_REGISTER 23 */ #define PHY_INTERRUPT_MASK 0x18 /* #define TRU_VMI_INTERRUPT_MASK_REGISTER 24 */ #define PHY_INTERRUPT_STATUS 0x19 /* #define TRU_VMI_INTERRUPT_STATUS_REGISTER 25 */ #define PHY_PHY_STATUS 0x1A /* #define TRU_VMI_PHY_STATUS_REGISTER 26 */ #define PHY_LED_1 0x1B /* #define TRU_VMI_LED_CONTROL_1_REGISTER 27 */ #define PHY_LED_2 0x1C /* #define TRU_VMI_LED_CONTROL_2_REGISTER 28 */ /* #define TRU_VMI_LINK_CONTROL_REGISTER 29 */ /* #define TRU_VMI_TIMING_CONTROL_REGISTER */ #endif /* _ET1310_PHY_H_ */