/* SPDX-License-Identifier: GPL-2.0 */ /* * Copyright (C) 2018-2022 Marvell International Ltd. * * Interface to the SMI/MDIO hardware, including support for both IEEE 802.3 * clause 22 and clause 45 operations. */ #ifndef __CVMX_MIO_H__ #define __CVMX_MIO_H__ /** * PHY register 0 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_CONTROL 0 typedef union { u16 u16; struct { u16 reset : 1; u16 loopback : 1; u16 speed_lsb : 1; u16 autoneg_enable : 1; u16 power_down : 1; u16 isolate : 1; u16 restart_autoneg : 1; u16 duplex : 1; u16 collision_test : 1; u16 speed_msb : 1; u16 unidirectional_enable : 1; u16 reserved_0_4 : 5; } s; } cvmx_mdio_phy_reg_control_t; /** * PHY register 1 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_STATUS 1 typedef union { u16 u16; struct { u16 capable_100base_t4 : 1; u16 capable_100base_x_full : 1; u16 capable_100base_x_half : 1; u16 capable_10_full : 1; u16 capable_10_half : 1; u16 capable_100base_t2_full : 1; u16 capable_100base_t2_half : 1; u16 capable_extended_status : 1; u16 capable_unidirectional : 1; u16 capable_mf_preamble_suppression : 1; u16 autoneg_complete : 1; u16 remote_fault : 1; u16 capable_autoneg : 1; u16 link_status : 1; u16 jabber_detect : 1; u16 capable_extended_registers : 1; } s; } cvmx_mdio_phy_reg_status_t; /** * PHY register 2 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_ID1 2 typedef union { u16 u16; struct { u16 oui_bits_3_18; } s; } cvmx_mdio_phy_reg_id1_t; /** * PHY register 3 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_ID2 3 typedef union { u16 u16; struct { u16 oui_bits_19_24 : 6; u16 model : 6; u16 revision : 4; } s; } cvmx_mdio_phy_reg_id2_t; /** * PHY register 4 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_AUTONEG_ADVER 4 typedef union { u16 u16; struct { u16 next_page : 1; u16 reserved_14 : 1; u16 remote_fault : 1; u16 reserved_12 : 1; u16 asymmetric_pause : 1; u16 pause : 1; u16 advert_100base_t4 : 1; u16 advert_100base_tx_full : 1; u16 advert_100base_tx_half : 1; u16 advert_10base_tx_full : 1; u16 advert_10base_tx_half : 1; u16 selector : 5; } s; } cvmx_mdio_phy_reg_autoneg_adver_t; /** * PHY register 5 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_LINK_PARTNER_ABILITY 5 typedef union { u16 u16; struct { u16 next_page : 1; u16 ack : 1; u16 remote_fault : 1; u16 reserved_12 : 1; u16 asymmetric_pause : 1; u16 pause : 1; u16 advert_100base_t4 : 1; u16 advert_100base_tx_full : 1; u16 advert_100base_tx_half : 1; u16 advert_10base_tx_full : 1; u16 advert_10base_tx_half : 1; u16 selector : 5; } s; } cvmx_mdio_phy_reg_link_partner_ability_t; /** * PHY register 6 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_AUTONEG_EXPANSION 6 typedef union { u16 u16; struct { u16 reserved_5_15 : 11; u16 parallel_detection_fault : 1; u16 link_partner_next_page_capable : 1; u16 local_next_page_capable : 1; u16 page_received : 1; u16 link_partner_autoneg_capable : 1; } s; } cvmx_mdio_phy_reg_autoneg_expansion_t; /** * PHY register 9 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_CONTROL_1000 9 typedef union { u16 u16; struct { u16 test_mode : 3; u16 manual_master_slave : 1; u16 master : 1; u16 port_type : 1; u16 advert_1000base_t_full : 1; u16 advert_1000base_t_half : 1; u16 reserved_0_7 : 8; } s; } cvmx_mdio_phy_reg_control_1000_t; /** * PHY register 10 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_STATUS_1000 10 typedef union { u16 u16; struct { u16 master_slave_fault : 1; u16 is_master : 1; u16 local_receiver_ok : 1; u16 remote_receiver_ok : 1; u16 remote_capable_1000base_t_full : 1; u16 remote_capable_1000base_t_half : 1; u16 reserved_8_9 : 2; u16 idle_error_count : 8; } s; } cvmx_mdio_phy_reg_status_1000_t; /** * PHY register 15 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_EXTENDED_STATUS 15 typedef union { u16 u16; struct { u16 capable_1000base_x_full : 1; u16 capable_1000base_x_half : 1; u16 capable_1000base_t_full : 1; u16 capable_1000base_t_half : 1; u16 reserved_0_11 : 12; } s; } cvmx_mdio_phy_reg_extended_status_t; /** * PHY register 13 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_MMD_CONTROL 13 typedef union { u16 u16; struct { u16 function : 2; u16 reserved_5_13 : 9; u16 devad : 5; } s; } cvmx_mdio_phy_reg_mmd_control_t; /** * PHY register 14 from the 802.3 spec */ #define CVMX_MDIO_PHY_REG_MMD_ADDRESS_DATA 14 typedef union { u16 u16; struct { u16 address_data : 16; } s; } cvmx_mdio_phy_reg_mmd_address_data_t; /* Operating request encodings. */ #define MDIO_CLAUSE_22_WRITE 0 #define MDIO_CLAUSE_22_READ 1 #define MDIO_CLAUSE_45_ADDRESS 0 #define MDIO_CLAUSE_45_WRITE 1 #define MDIO_CLAUSE_45_READ_INC 2 #define MDIO_CLAUSE_45_READ 3 /* MMD identifiers, mostly for accessing devices within XENPAK modules. */ #define CVMX_MMD_DEVICE_PMA_PMD 1 #define CVMX_MMD_DEVICE_WIS 2 #define CVMX_MMD_DEVICE_PCS 3 #define CVMX_MMD_DEVICE_PHY_XS 4 #define CVMX_MMD_DEVICE_DTS_XS 5 #define CVMX_MMD_DEVICE_TC 6 #define CVMX_MMD_DEVICE_CL22_EXT 29 #define CVMX_MMD_DEVICE_VENDOR_1 30 #define CVMX_MMD_DEVICE_VENDOR_2 31 #define CVMX_MDIO_TIMEOUT 100000 /* 100 millisec */ static inline int cvmx_mdio_bus_id_to_node(int bus_id) { if (OCTEON_IS_MODEL(OCTEON_CN78XX)) return (bus_id >> 2) & CVMX_NODE_MASK; else return 0; } static inline int cvmx_mdio_bus_id_to_bus(int bus_id) { if (OCTEON_IS_MODEL(OCTEON_CN78XX)) return bus_id & 3; else return bus_id; } /* Helper function to put MDIO interface into clause 45 mode */ static inline void __cvmx_mdio_set_clause45_mode(int bus_id) { cvmx_smix_clk_t smi_clk; int node = cvmx_mdio_bus_id_to_node(bus_id); int bus = cvmx_mdio_bus_id_to_bus(bus_id); /* Put bus into clause 45 mode */ smi_clk.u64 = csr_rd_node(node, CVMX_SMIX_CLK(bus)); smi_clk.s.mode = 1; smi_clk.s.preamble = 1; csr_wr_node(node, CVMX_SMIX_CLK(bus), smi_clk.u64); } /* Helper function to put MDIO interface into clause 22 mode */ static inline void __cvmx_mdio_set_clause22_mode(int bus_id) { cvmx_smix_clk_t smi_clk; int node = cvmx_mdio_bus_id_to_node(bus_id); int bus = cvmx_mdio_bus_id_to_bus(bus_id); /* Put bus into clause 22 mode */ smi_clk.u64 = csr_rd_node(node, CVMX_SMIX_CLK(bus)); smi_clk.s.mode = 0; csr_wr_node(node, CVMX_SMIX_CLK(bus), smi_clk.u64); } /** * @INTERNAL * Function to read SMIX_RD_DAT and check for timeouts. This * code sequence is done fairly often, so put in one spot. * * @param bus_id SMI/MDIO bus to read * * @return Value of SMIX_RD_DAT. pending will be set on * a timeout. */ static inline cvmx_smix_rd_dat_t __cvmx_mdio_read_rd_dat(int bus_id) { cvmx_smix_rd_dat_t smi_rd; int node = cvmx_mdio_bus_id_to_node(bus_id); int bus = cvmx_mdio_bus_id_to_bus(bus_id); u64 done; done = get_timer(0); do { mdelay(1); smi_rd.u64 = csr_rd_node(node, CVMX_SMIX_RD_DAT(bus)); if (get_timer(done) > (CVMX_MDIO_TIMEOUT / 1000)) break; } while (smi_rd.s.pending); return smi_rd; } /** * Perform an MII read. This function is used to read PHY * registers controlling auto negotiation. * * @param bus_id MDIO bus number. Zero on most chips, but some chips (ex CN56XX) * support multiple busses. * @param phy_id The MII phy id * @param location Register location to read * * @return Result from the read or -1 on failure */ static inline int cvmx_mdio_read(int bus_id, int phy_id, int location) { int node = cvmx_mdio_bus_id_to_node(bus_id); int bus = cvmx_mdio_bus_id_to_bus(bus_id); cvmx_smix_cmd_t smi_cmd; cvmx_smix_rd_dat_t smi_rd; if (octeon_has_feature(OCTEON_FEATURE_MDIO_CLAUSE_45)) __cvmx_mdio_set_clause22_mode(bus_id); smi_cmd.u64 = 0; smi_cmd.s.phy_op = MDIO_CLAUSE_22_READ; smi_cmd.s.phy_adr = phy_id; smi_cmd.s.reg_adr = location; csr_wr_node(node, CVMX_SMIX_CMD(bus), smi_cmd.u64); smi_rd = __cvmx_mdio_read_rd_dat(bus_id); if (smi_rd.s.val) return smi_rd.s.dat; else return -1; } /** * Perform an MII write. This function is used to write PHY * registers controlling auto negotiation. * * @param bus_id MDIO bus number. Zero on most chips, but some chips (ex CN56XX) * support multiple busses. * @param phy_id The MII phy id * @param location Register location to write * @param val Value to write * * @return -1 on error * 0 on success */ static inline int cvmx_mdio_write(int bus_id, int phy_id, int location, int val) { int node = cvmx_mdio_bus_id_to_node(bus_id); int bus = cvmx_mdio_bus_id_to_bus(bus_id); cvmx_smix_cmd_t smi_cmd; cvmx_smix_wr_dat_t smi_wr; if (octeon_has_feature(OCTEON_FEATURE_MDIO_CLAUSE_45)) __cvmx_mdio_set_clause22_mode(bus_id); smi_wr.u64 = 0; smi_wr.s.dat = val; csr_wr_node(node, CVMX_SMIX_WR_DAT(bus), smi_wr.u64); smi_cmd.u64 = 0; smi_cmd.s.phy_op = MDIO_CLAUSE_22_WRITE; smi_cmd.s.phy_adr = phy_id; smi_cmd.s.reg_adr = location; csr_wr_node(node, CVMX_SMIX_CMD(bus), smi_cmd.u64); if (CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_SMIX_WR_DAT(bus), cvmx_smix_wr_dat_t, pending, ==, 0, CVMX_MDIO_TIMEOUT)) return -1; return 0; } /** * Perform an IEEE 802.3 clause 45 MII read. This function is used to read PHY * registers controlling auto negotiation. * * @param bus_id MDIO bus number. Zero on most chips, but some chips (ex CN56XX) * support multiple busses. * @param phy_id The MII phy id * @param device MDIO Manageable Device (MMD) id * @param location Register location to read * * @return Result from the read or -1 on failure */ static inline int cvmx_mdio_45_read(int bus_id, int phy_id, int device, int location) { cvmx_smix_cmd_t smi_cmd; cvmx_smix_rd_dat_t smi_rd; cvmx_smix_wr_dat_t smi_wr; int node = cvmx_mdio_bus_id_to_node(bus_id); int bus = cvmx_mdio_bus_id_to_bus(bus_id); if (!octeon_has_feature(OCTEON_FEATURE_MDIO_CLAUSE_45)) return -1; __cvmx_mdio_set_clause45_mode(bus_id); smi_wr.u64 = 0; smi_wr.s.dat = location; csr_wr_node(node, CVMX_SMIX_WR_DAT(bus), smi_wr.u64); smi_cmd.u64 = 0; smi_cmd.s.phy_op = MDIO_CLAUSE_45_ADDRESS; smi_cmd.s.phy_adr = phy_id; smi_cmd.s.reg_adr = device; csr_wr_node(node, CVMX_SMIX_CMD(bus), smi_cmd.u64); if (CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_SMIX_WR_DAT(bus), cvmx_smix_wr_dat_t, pending, ==, 0, CVMX_MDIO_TIMEOUT)) { debug("cvmx_mdio_45_read: bus_id %d phy_id %2d device %2d register %2d TIME OUT(address)\n", bus_id, phy_id, device, location); return -1; } smi_cmd.u64 = 0; smi_cmd.s.phy_op = MDIO_CLAUSE_45_READ; smi_cmd.s.phy_adr = phy_id; smi_cmd.s.reg_adr = device; csr_wr_node(node, CVMX_SMIX_CMD(bus), smi_cmd.u64); smi_rd = __cvmx_mdio_read_rd_dat(bus_id); if (smi_rd.s.pending) { debug("cvmx_mdio_45_read: bus_id %d phy_id %2d device %2d register %2d TIME OUT(data)\n", bus_id, phy_id, device, location); return -1; } if (smi_rd.s.val) return smi_rd.s.dat; debug("cvmx_mdio_45_read: bus_id %d phy_id %2d device %2d register %2d INVALID READ\n", bus_id, phy_id, device, location); return -1; } /** * Perform an IEEE 802.3 clause 45 MII write. This function is used to write PHY * registers controlling auto negotiation. * * @param bus_id MDIO bus number. Zero on most chips, but some chips (ex CN56XX) * support multiple busses. * @param phy_id The MII phy id * @param device MDIO Manageable Device (MMD) id * @param location Register location to write * @param val Value to write * * @return -1 on error * 0 on success */ static inline int cvmx_mdio_45_write(int bus_id, int phy_id, int device, int location, int val) { cvmx_smix_cmd_t smi_cmd; cvmx_smix_wr_dat_t smi_wr; int node = cvmx_mdio_bus_id_to_node(bus_id); int bus = cvmx_mdio_bus_id_to_bus(bus_id); if (!octeon_has_feature(OCTEON_FEATURE_MDIO_CLAUSE_45)) return -1; __cvmx_mdio_set_clause45_mode(bus_id); smi_wr.u64 = 0; smi_wr.s.dat = location; csr_wr_node(node, CVMX_SMIX_WR_DAT(bus), smi_wr.u64); smi_cmd.u64 = 0; smi_cmd.s.phy_op = MDIO_CLAUSE_45_ADDRESS; smi_cmd.s.phy_adr = phy_id; smi_cmd.s.reg_adr = device; csr_wr_node(node, CVMX_SMIX_CMD(bus), smi_cmd.u64); if (CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_SMIX_WR_DAT(bus), cvmx_smix_wr_dat_t, pending, ==, 0, CVMX_MDIO_TIMEOUT)) return -1; smi_wr.u64 = 0; smi_wr.s.dat = val; csr_wr_node(node, CVMX_SMIX_WR_DAT(bus), smi_wr.u64); smi_cmd.u64 = 0; smi_cmd.s.phy_op = MDIO_CLAUSE_45_WRITE; smi_cmd.s.phy_adr = phy_id; smi_cmd.s.reg_adr = device; csr_wr_node(node, CVMX_SMIX_CMD(bus), smi_cmd.u64); if (CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_SMIX_WR_DAT(bus), cvmx_smix_wr_dat_t, pending, ==, 0, CVMX_MDIO_TIMEOUT)) return -1; return 0; } #endif