/* * Copyright (c) 2023 hpmicro * * SPDX-License-Identifier: BSD-3-Clause * * Change Logs: * Date Author Notes * 2022-01-11 hpmicro First version */ #include "rtthread.h" #ifdef RT_USING_PHY #include #include #include "hpm_enet_drv.h" #include "eth_phy_port.h" #include "hpm_soc.h" #include "netif/ethernetif.h" #include "board.h" typedef struct { char *mdio_name; ENET_Type *instance; struct eth_device *eth_dev; phy_device_t *phy_dev; struct rt_mdio_bus *mdio_bus; } eth_phy_handle_t; typedef struct { uint8_t phy_handle_cnt; eth_phy_handle_t **phy_handle; } eth_phy_monitor_handle_t; #ifdef BSP_USING_ETH0 extern struct eth_device eth0_dev; static struct rt_mdio_bus mdio0_bus; static phy_device_t phy0_dev; static uint8_t phy0_reg_list[]= {PHY0_REG_LIST}; static eth_phy_handle_t eth0_phy_handle = { .instance = HPM_ENET0, .eth_dev = ð0_dev, .phy_dev = &phy0_dev, .mdio_name = "MDIO0", .mdio_bus = &mdio0_bus, }; #endif #ifdef BSP_USING_ETH1 extern struct eth_device eth1_dev; static struct rt_mdio_bus mdio1_bus; static phy_device_t phy1_dev; static uint8_t phy1_reg_list[]= {PHY1_REG_LIST}; static eth_phy_handle_t eth1_phy_handle = { .instance = HPM_ENET1, .eth_dev = ð1_dev, .phy_dev = &phy1_dev, .mdio_name = "MDIO1", .mdio_bus = &mdio1_bus, }; #endif static eth_phy_handle_t *s_gphys[] = { #ifdef BSP_USING_ETH0 ð0_phy_handle, #endif #ifdef BSP_USING_ETH1 ð1_phy_handle #endif }; static uint8_t *s_gphy_reg_list[] = { #ifdef BSP_USING_ETH0 phy0_reg_list, #endif #ifdef BSP_USING_ETH1 phy1_reg_list, #endif }; eth_phy_monitor_handle_t phy_monitor_handle = { .phy_handle_cnt = ARRAY_SIZE(s_gphys), .phy_handle = s_gphys }; static struct rt_phy_ops phy_ops; static rt_phy_status phy_init(void *object, rt_uint32_t phy_addr, rt_uint32_t src_clock_hz) { #ifdef BSP_USING_ETH0 return PHY_STATUS_OK; #endif #ifdef BSP_USING_ETH1 rtl8201_config_t phy_config; rtl8201_reset((ENET_Type *)object); rtl8201_basic_mode_default_config((ENET_Type *)object, &phy_config); if (rtl8201_basic_mode_init((ENET_Type *)object, &phy_config) == true) { return PHY_STATUS_OK; } else { return PHY_STATUS_FAIL; } #endif } static rt_size_t phy_read(void *bus, rt_uint32_t addr, rt_uint32_t reg, void *data, rt_uint32_t size) { *(uint16_t *)data = enet_read_phy(((struct rt_mdio_bus *)bus)->hw_obj, addr, reg); return size; } static rt_size_t phy_write(void *bus, rt_uint32_t addr, rt_uint32_t reg, void *data, rt_uint32_t size) { enet_write_phy(((struct rt_mdio_bus *)bus)->hw_obj, addr, reg, *(uint16_t *)data); return size; } static rt_phy_status phy_get_link_status(rt_phy_t *phy, rt_bool_t *status) { uint16_t reg_status; reg_status = enet_read_phy(phy->bus->hw_obj, phy->addr, phy->reg_list[PHY_BASIC_STATUS_REG_IDX]); #if PHY_AUTO_NEGO reg_status &= PHY_AUTONEGO_COMPLETE_MASK | PHY_LINKED_STATUS_MASK; *status = reg_status ? RT_TRUE : RT_FALSE; #else reg_status &= PHY_LINKED_STATUS_MASK; *status = reg_status ? RT_TRUE : RT_FALSE; #endif return PHY_STATUS_OK; } static rt_phy_status phy_get_link_speed_duplex(rt_phy_t *phy, rt_uint32_t *speed, rt_uint32_t *duplex) { uint16_t reg_status; reg_status = enet_read_phy(phy->bus->hw_obj, phy->addr, phy->reg_list[PHY_STATUS_REG_IDX]); #if RGMII if (PHY_STATUS_SPEED_1000M(reg_status)) { *speed = PHY_SPEED_1000M; } else if (PHY_STATUS_SPEED_100M(reg_status)) { *speed = PHY_SPEED_100M; } else { *speed = PHY_SPEED_10M; } #else if (PHY_STATUS_SPEED_100M(reg_status)) { *speed = PHY_SPEED_100M; } else { *speed = PHY_SPEED_10M; } #endif *duplex = PHY_STATUS_FULL_DUPLEX(reg_status) ? PHY_FULL_DUPLEX: PHY_HALF_DUPLEX; return PHY_STATUS_OK; } static void phy_poll_status(void *parameter) { int ret; phy_info_t phy_info; rt_bool_t status; rt_device_t dev; rt_phy_msg_t msg; rt_uint32_t speed, duplex; phy_device_t *phy_dev; struct eth_device* eth_dev; char const *ps[] = {"10Mbps", "100Mbps", "1000Mbps"}; enet_line_speed_t line_speed[] = {enet_line_speed_10mbps, enet_line_speed_100mbps, enet_line_speed_1000mbps}; eth_phy_monitor_handle_t *phy_monitor_handle = (eth_phy_monitor_handle_t *)parameter; for (uint32_t i = 0; i < phy_monitor_handle->phy_handle_cnt; i++) { eth_dev = phy_monitor_handle->phy_handle[i]->eth_dev; phy_dev = phy_monitor_handle->phy_handle[i]->phy_dev; phy_dev->phy.ops->get_link_status(&phy_dev->phy, &status); if (status) { phy_dev->phy.ops->get_link_speed_duplex(&phy_dev->phy, &phy_info.phy_speed, &phy_info.phy_duplex); ret = memcmp(&phy_dev->phy_info, &phy_info, sizeof(phy_info_t)); if (ret != 0) { memcpy(&phy_dev->phy_info, &phy_info, sizeof(phy_info_t)); } } if (phy_dev->phy_link != status) { phy_dev->phy_link = status ? PHY_LINK_UP : PHY_LINK_DOWN; eth_device_linkchange(eth_dev, status); LOG_I("PHY Status: %s", status ? "Link up" : "Link down\n"); if (status == PHY_LINK_UP) { LOG_I("PHY Speed: %s", ps[phy_dev->phy_info.phy_speed]); LOG_I("PHY Duplex: %s\n", phy_dev->phy_info.phy_duplex & PHY_FULL_DUPLEX ? "full duplex" : "half duplex"); enet_set_line_speed(phy_monitor_handle->phy_handle[i]->instance, line_speed[phy_dev->phy_info.phy_speed]); enet_set_duplex_mode(phy_monitor_handle->phy_handle[i]->instance, phy_dev->phy_info.phy_duplex); } } } } static void phy_detection(void *parameter) { uint8_t detected_count = 0; struct rt_phy_msg msg = {0, 0}; phy_device_t *phy_dev = (phy_device_t *)parameter; rt_uint32_t i; msg.reg = phy_dev->phy.reg_list[PHY_ID1_REG_IDX]; while(phy_dev->phy.addr == 0xffff) { /* Search a PHY */ for (i = 0; i <= 0x1f; i++) { ((rt_phy_t *)(phy_dev->phy.parent.user_data))->addr = i; phy_dev->phy.parent.read(&(phy_dev->phy.parent), 0, &msg, 1); if (msg.value == PHY_ID1) { phy_dev->phy.addr = i; LOG_D("Found a PHY device[address:0x%02x].\n", phy_dev->phy.addr); phy_dev->phy.ops->init(phy_dev->phy.bus->hw_obj, phy_dev->phy.addr, PHY_MDIO_CSR_CLK_FREQ); return; } } phy_dev->phy.addr = 0xffff; detected_count++; rt_thread_mdelay(1000); if (detected_count > 3) { LOG_E("No any PHY device is detected! Please check your hardware!\n"); return; } } } static void phy_monitor_thread_entry(void *args) { rt_timer_t phy_status_timer; eth_phy_monitor_handle_t *phy_monitor_handle = (eth_phy_monitor_handle_t *)args; for (uint32_t i = 0; i < phy_monitor_handle->phy_handle_cnt; i++) { LOG_D("Detect a PHY%d\n", i); phy_detection(phy_monitor_handle->phy_handle[i]->phy_dev); } phy_status_timer = rt_timer_create("PHY_Monitor", phy_poll_status, phy_monitor_handle, RT_TICK_PER_SECOND, RT_TIMER_FLAG_PERIODIC | RT_TIMER_FLAG_SOFT_TIMER); if (!phy_status_timer || rt_timer_start(phy_status_timer) != RT_EOK) { LOG_E("Failed to start link change detection timer\n"); } } int phy_device_register(void) { rt_err_t err = RT_ERROR; rt_thread_t thread_phy_monitor; /* Set ops for PHY */ phy_ops.init = phy_init; phy_ops.get_link_status = phy_get_link_status; phy_ops.get_link_speed_duplex = phy_get_link_speed_duplex; for (uint32_t i = 0; i < ARRAY_SIZE(s_gphys); i++) { /* Set PHY address */ s_gphys[i]->phy_dev->phy.addr = 0xffff; /* Set MIDO bus */ s_gphys[i]->mdio_bus->hw_obj = s_gphys[i]->instance; s_gphys[i]->mdio_bus->name = s_gphys[i]->mdio_name; s_gphys[i]->mdio_bus->ops->read = phy_read; s_gphys[i]->mdio_bus->ops->write = phy_write; s_gphys[i]->phy_dev->phy.bus = s_gphys[i]->mdio_bus; s_gphys[i]->phy_dev->phy.ops = &phy_ops; /* Set PHY register list */ s_gphys[i]->phy_dev->phy.reg_list = s_gphy_reg_list[i]; rt_hw_phy_register(&s_gphys[i]->phy_dev->phy, PHY_NAME); } /* Start PHY monitor */ thread_phy_monitor = rt_thread_create("PHY Monitor", phy_monitor_thread_entry, &phy_monitor_handle, 1024, RT_THREAD_PRIORITY_MAX - 2, 2); if (thread_phy_monitor != RT_NULL) { rt_thread_startup(thread_phy_monitor); } else { err = RT_ERROR; } return err; } INIT_PREV_EXPORT(phy_device_register); #endif /* RT_USING_PHY */