/* * Copyright (c) 2014-2015 Hisilicon Limited. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. */ #include "hns_dsaf_mac.h" #include "hns_dsaf_misc.h" #include "hns_dsaf_ppe.h" #include "hns_dsaf_reg.h" static void dsaf_write_sub(struct dsaf_device *dsaf_dev, u32 reg, u32 val) { if (dsaf_dev->sub_ctrl) dsaf_write_syscon(dsaf_dev->sub_ctrl, reg, val); else dsaf_write_reg(dsaf_dev->sc_base, reg, val); } static u32 dsaf_read_sub(struct dsaf_device *dsaf_dev, u32 reg) { u32 ret; if (dsaf_dev->sub_ctrl) ret = dsaf_read_syscon(dsaf_dev->sub_ctrl, reg); else ret = dsaf_read_reg(dsaf_dev->sc_base, reg); return ret; } void hns_cpld_set_led(struct hns_mac_cb *mac_cb, int link_status, u16 speed, int data) { int speed_reg = 0; u8 value; if (!mac_cb) { pr_err("sfp_led_opt mac_dev is null!\n"); return; } if (!mac_cb->cpld_ctrl) { dev_err(mac_cb->dev, "mac_id=%d, cpld syscon is null !\n", mac_cb->mac_id); return; } if (speed == MAC_SPEED_10000) speed_reg = 1; value = mac_cb->cpld_led_value; if (link_status) { dsaf_set_bit(value, DSAF_LED_LINK_B, link_status); dsaf_set_field(value, DSAF_LED_SPEED_M, DSAF_LED_SPEED_S, speed_reg); dsaf_set_bit(value, DSAF_LED_DATA_B, data); if (value != mac_cb->cpld_led_value) { dsaf_write_syscon(mac_cb->cpld_ctrl, mac_cb->cpld_ctrl_reg, value); mac_cb->cpld_led_value = value; } } else { dsaf_write_syscon(mac_cb->cpld_ctrl, mac_cb->cpld_ctrl_reg, CPLD_LED_DEFAULT_VALUE); mac_cb->cpld_led_value = CPLD_LED_DEFAULT_VALUE; } } void cpld_led_reset(struct hns_mac_cb *mac_cb) { if (!mac_cb || !mac_cb->cpld_ctrl) return; dsaf_write_syscon(mac_cb->cpld_ctrl, mac_cb->cpld_ctrl_reg, CPLD_LED_DEFAULT_VALUE); mac_cb->cpld_led_value = CPLD_LED_DEFAULT_VALUE; } int cpld_set_led_id(struct hns_mac_cb *mac_cb, enum hnae_led_state status) { switch (status) { case HNAE_LED_ACTIVE: mac_cb->cpld_led_value = dsaf_read_syscon(mac_cb->cpld_ctrl, mac_cb->cpld_ctrl_reg); dsaf_set_bit(mac_cb->cpld_led_value, DSAF_LED_ANCHOR_B, CPLD_LED_ON_VALUE); dsaf_write_syscon(mac_cb->cpld_ctrl, mac_cb->cpld_ctrl_reg, mac_cb->cpld_led_value); return 2; case HNAE_LED_INACTIVE: dsaf_set_bit(mac_cb->cpld_led_value, DSAF_LED_ANCHOR_B, CPLD_LED_DEFAULT_VALUE); dsaf_write_syscon(mac_cb->cpld_ctrl, mac_cb->cpld_ctrl_reg, mac_cb->cpld_led_value); break; default: break; } return 0; } #define RESET_REQ_OR_DREQ 1 void hns_dsaf_rst(struct dsaf_device *dsaf_dev, u32 val) { u32 xbar_reg_addr; u32 nt_reg_addr; if (!val) { xbar_reg_addr = DSAF_SUB_SC_XBAR_RESET_REQ_REG; nt_reg_addr = DSAF_SUB_SC_NT_RESET_REQ_REG; } else { xbar_reg_addr = DSAF_SUB_SC_XBAR_RESET_DREQ_REG; nt_reg_addr = DSAF_SUB_SC_NT_RESET_DREQ_REG; } dsaf_write_sub(dsaf_dev, xbar_reg_addr, RESET_REQ_OR_DREQ); dsaf_write_sub(dsaf_dev, nt_reg_addr, RESET_REQ_OR_DREQ); } void hns_dsaf_xge_srst_by_port(struct dsaf_device *dsaf_dev, u32 port, u32 val) { u32 reg_val = 0; u32 reg_addr; if (port >= DSAF_XGE_NUM) return; reg_val |= RESET_REQ_OR_DREQ; reg_val |= 0x2082082 << dsaf_dev->mac_cb[port]->port_rst_off; if (val == 0) reg_addr = DSAF_SUB_SC_XGE_RESET_REQ_REG; else reg_addr = DSAF_SUB_SC_XGE_RESET_DREQ_REG; dsaf_write_sub(dsaf_dev, reg_addr, reg_val); } void hns_dsaf_xge_core_srst_by_port(struct dsaf_device *dsaf_dev, u32 port, u32 val) { u32 reg_val = 0; u32 reg_addr; if (port >= DSAF_XGE_NUM) return; reg_val |= XGMAC_TRX_CORE_SRST_M << dsaf_dev->mac_cb[port]->port_rst_off; if (val == 0) reg_addr = DSAF_SUB_SC_XGE_RESET_REQ_REG; else reg_addr = DSAF_SUB_SC_XGE_RESET_DREQ_REG; dsaf_write_sub(dsaf_dev, reg_addr, reg_val); } void hns_dsaf_ge_srst_by_port(struct dsaf_device *dsaf_dev, u32 port, u32 val) { u32 reg_val_1; u32 reg_val_2; u32 port_rst_off; if (port >= DSAF_GE_NUM) return; if (!HNS_DSAF_IS_DEBUG(dsaf_dev)) { reg_val_1 = 0x1 << port; port_rst_off = dsaf_dev->mac_cb[port]->port_rst_off; /* there is difference between V1 and V2 in register.*/ if (AE_IS_VER1(dsaf_dev->dsaf_ver)) reg_val_2 = 0x1041041 << port_rst_off; else reg_val_2 = 0x2082082 << port_rst_off; if (val == 0) { dsaf_write_sub(dsaf_dev, DSAF_SUB_SC_GE_RESET_REQ1_REG, reg_val_1); dsaf_write_sub(dsaf_dev, DSAF_SUB_SC_GE_RESET_REQ0_REG, reg_val_2); } else { dsaf_write_sub(dsaf_dev, DSAF_SUB_SC_GE_RESET_DREQ0_REG, reg_val_2); dsaf_write_sub(dsaf_dev, DSAF_SUB_SC_GE_RESET_DREQ1_REG, reg_val_1); } } else { reg_val_1 = 0x15540 << dsaf_dev->reset_offset; reg_val_2 = 0x100 << dsaf_dev->reset_offset; if (val == 0) { dsaf_write_sub(dsaf_dev, DSAF_SUB_SC_GE_RESET_REQ1_REG, reg_val_1); dsaf_write_sub(dsaf_dev, DSAF_SUB_SC_PPE_RESET_REQ_REG, reg_val_2); } else { dsaf_write_sub(dsaf_dev, DSAF_SUB_SC_GE_RESET_DREQ1_REG, reg_val_1); dsaf_write_sub(dsaf_dev, DSAF_SUB_SC_PPE_RESET_DREQ_REG, reg_val_2); } } } void hns_ppe_srst_by_port(struct dsaf_device *dsaf_dev, u32 port, u32 val) { u32 reg_val = 0; u32 reg_addr; reg_val |= RESET_REQ_OR_DREQ << dsaf_dev->mac_cb[port]->port_rst_off; if (val == 0) reg_addr = DSAF_SUB_SC_PPE_RESET_REQ_REG; else reg_addr = DSAF_SUB_SC_PPE_RESET_DREQ_REG; dsaf_write_sub(dsaf_dev, reg_addr, reg_val); } void hns_ppe_com_srst(struct ppe_common_cb *ppe_common, u32 val) { struct dsaf_device *dsaf_dev = ppe_common->dsaf_dev; u32 reg_val; u32 reg_addr; if (!HNS_DSAF_IS_DEBUG(dsaf_dev)) { reg_val = RESET_REQ_OR_DREQ; if (val == 0) reg_addr = DSAF_SUB_SC_RCB_PPE_COM_RESET_REQ_REG; else reg_addr = DSAF_SUB_SC_RCB_PPE_COM_RESET_DREQ_REG; } else { reg_val = 0x100 << dsaf_dev->reset_offset; if (val == 0) reg_addr = DSAF_SUB_SC_PPE_RESET_REQ_REG; else reg_addr = DSAF_SUB_SC_PPE_RESET_DREQ_REG; } dsaf_write_sub(dsaf_dev, reg_addr, reg_val); } /** * hns_mac_get_sds_mode - get phy ifterface form serdes mode * @mac_cb: mac control block * retuen phy interface */ phy_interface_t hns_mac_get_phy_if(struct hns_mac_cb *mac_cb) { u32 mode; u32 reg; bool is_ver1 = AE_IS_VER1(mac_cb->dsaf_dev->dsaf_ver); int mac_id = mac_cb->mac_id; phy_interface_t phy_if; if (is_ver1) { if (HNS_DSAF_IS_DEBUG(mac_cb->dsaf_dev)) return PHY_INTERFACE_MODE_SGMII; if (mac_id >= 0 && mac_id <= 3) reg = HNS_MAC_HILINK4_REG; else reg = HNS_MAC_HILINK3_REG; } else{ if (!HNS_DSAF_IS_DEBUG(mac_cb->dsaf_dev) && mac_id <= 3) reg = HNS_MAC_HILINK4V2_REG; else reg = HNS_MAC_HILINK3V2_REG; } mode = dsaf_read_sub(mac_cb->dsaf_dev, reg); if (dsaf_get_bit(mode, mac_cb->port_mode_off)) phy_if = PHY_INTERFACE_MODE_XGMII; else phy_if = PHY_INTERFACE_MODE_SGMII; return phy_if; } int hns_mac_get_sfp_prsnt(struct hns_mac_cb *mac_cb, int *sfp_prsnt) { if (!mac_cb->cpld_ctrl) return -ENODEV; *sfp_prsnt = !dsaf_read_syscon(mac_cb->cpld_ctrl, mac_cb->cpld_ctrl_reg + MAC_SFP_PORT_OFFSET); return 0; } /** * hns_mac_config_sds_loopback - set loop back for serdes * @mac_cb: mac control block * retuen 0 == success */ int hns_mac_config_sds_loopback(struct hns_mac_cb *mac_cb, u8 en) { /* port 0-3 hilink4 base is serdes_vaddr + 0x00280000 * port 4-7 hilink3 base is serdes_vaddr + 0x00200000 */ u8 *base_addr = (u8 *)mac_cb->serdes_vaddr + (mac_cb->mac_id <= 3 ? 0x00280000 : 0x00200000); const u8 lane_id[] = { 0, /* mac 0 -> lane 0 */ 1, /* mac 1 -> lane 1 */ 2, /* mac 2 -> lane 2 */ 3, /* mac 3 -> lane 3 */ 2, /* mac 4 -> lane 2 */ 3, /* mac 5 -> lane 3 */ 0, /* mac 6 -> lane 0 */ 1 /* mac 7 -> lane 1 */ }; #define RX_CSR(lane, reg) ((0x4080 + (reg) * 0x0002 + (lane) * 0x0200) * 2) u64 reg_offset = RX_CSR(lane_id[mac_cb->mac_id], 0); int sfp_prsnt; int ret = hns_mac_get_sfp_prsnt(mac_cb, &sfp_prsnt); if (!mac_cb->phy_node) { if (ret) pr_info("please confirm sfp is present or not\n"); else if (!sfp_prsnt) pr_info("no sfp in this eth\n"); } if (mac_cb->serdes_ctrl) { u32 origin = dsaf_read_syscon(mac_cb->serdes_ctrl, reg_offset); dsaf_set_field(origin, 1ull << 10, 10, !!en); dsaf_write_syscon(mac_cb->serdes_ctrl, reg_offset, origin); } else { dsaf_set_reg_field(base_addr, reg_offset, 1ull << 10, 10, !!en); } return 0; }