以太网

[英文]

概述

ESP-IDF 提供一系列功能强大且兼具一致性的 API,为内部以太网 MAC (EMAC) 控制器和外部 SPI-Ethernet 模块提供支持。

本编程指南分为以下几个部分:

以太网基本概念

以太网是一种异步的带冲突检测的载波侦听多路访问 (CSMA/CD) 协议/接口。通常来说,以太网不太适用于低功率应用。然而,得益于其广泛的部署、高效的网络连接、高数据率以及范围不限的可扩展性,几乎所有的有线通信都可以通过以太网进行。

符合 IEEE 802.3 标准的正常以太网帧的长度在 64 至 1518 字节之间,由五个或六个不同的字段组成:目的地 MAC 地址 (DA)、源 MAC 地址 (SA)、类型/长度字段、数据有效载荷字段、可选的填充字段和帧校验序列字段 (CRC)。此外,在以太网上传输时,以太网数据包的开头需附加 7 字节的前导码和 1 字节的帧起始符 (SOF)。

因此,双绞线上的通信如图所示:

以太网数据帧格式

前导码和帧起始符

前导码包含 7 字节的 55H,作用是使接收器在实际帧到达之前锁定数据流。

帧前界定符 (SFD) 为二进制序列 10101011 (物理介质层可见)。有时它也被视作前导码的一部分。

在传输和接收数据时,协议将自动从数据包中生成/移除前导码和帧起始符。

目的地址 (DA)

目的地址字段包含一个 6 字节长的设备 MAC 地址,数据包将发送到该地址。如果 MAC 地址第一个字节中的最低有效位是 1,则该地址为组播地址。例如,01-00-00-F0-00 和 33-45-67-89-AB-CD 是组播地址,而 00-00-00-F0-00 和 32-45-67-89-AB-CD 不是。

带有组播地址的数据包将到达选定的一组以太网节点,并发挥重要作用。如果目的地址字段是保留的多播地址,即 FF-FF-FF-FF-FF-FF,则该数据包是一个广播数据包,指向共享网络中的每个对象。如果 MAC 地址的第一个字节中的最低有效位为 0,则该地址为单播地址,仅供寻址节点使用。

通常,EMAC 控制器会集成接收过滤器,用于丢弃或接收带有组播、广播和/或单播目的地址的数据包。传输数据包时,由主机控制器将所需的目标地址写入传输缓冲区。

源地址 (SA)

源地址字段包含一个 6 字节长的节点 MAC 地址,以太网数据包通过该节点创建。以太网的用户需为所使用的任意控制器生成唯一的 MAC 地址。MAC 地址由两部分组成:前三个字节称为组织唯一标识符 (OUI),由 IEEE 分配;后三个字节是地址字节,由购买 OUI 的公司配置。有关 ESP-IDF 中使用的 MAC 地址的详细信息,请参见 MAC 地址分配

传输数据包时,由主机控制器将分配的源 MAC 地址写入传输缓冲区。

类型/长度

类型/长度字段长度为 2 字节。如果其值 <= 1500(十进制),则该字段为长度字段,指定在数据字段后的非填充数据量;如果其值 >= 1536,则该字段值表示后续数据包所属的协议。以下为该字段的常见值:

  • IPv4 = 0800H

  • IPv6 = 86DDH

  • ARP = 0806H

使用专有网络的用户可以将此字段配置为长度字段。然而,对于使用互联网协议 (IP) 或地址解析协议 (ARP) 等协议的应用程序,在传输数据包时,应将此字段配置为协议规范定义的适当类型。

数据有效载荷

数据有效载荷字段是一个可变长度的字段,长度从 0 到 1500 字节不等。更大的数据包会因违反以太网标准而被大多数以太网节点丢弃。

数据有效载荷字段包含客户端数据,如 IP 数据报。

填充及帧校验序列 (FCS)

填充字段是一个可变长度的字段。数据有效载荷较小时,将添加填充字段以满足 IEEE 802.3 规范的要求。

以太网数据包的 DA、SA、类型、数据有效载荷和填充字段共计必须不小于 60 字节。加上所需的 4 字节 FCS 字段,数据包的长度必须不小于 64 字节。如果数据有效载荷字段小于 46 字节,则需要加上一个填充字段。

帧校验序列字段 (FCS) 长度为 4 字节,其中包含一个行业标准的 32 位 CRC,该 CRC 是根据 DA、SA、类型、数据有效载荷和填充字段的数据计算的。鉴于计算 CRC 的复杂性,硬件通常会自动生成一个有效的 CRC 进行传输。否则,需由主机控制器生成 CRC 并将其写入传输缓冲区。

通常情况下,主机控制器无需关注填充字段和 CRC 字段,因为这两部分可以在传输或接收时由硬件 EMAC 自动生成或验证。然而,当数据包到达时,填充字段和 CRC 字段将被写入接收缓冲区。因此,如果需要的话,主机控制器也可以对它们进行评估。

备注

除了上述的基本数据帧,在 10/100 Mbps 以太网中还有两种常见的帧类型:控制帧和 VLAN 标记帧。ESP-IDF 不支持这两种帧类型。

配置 MAC 和 PHY

以太网驱动器由两部分组成:MAC 和 PHY。

MAC 和 PHY 之间的通信可以通过多种方式进行,如: MII (媒体独立接口)、 RMII (简化媒体独立接口)等。

以太网 RMII 接口

以太网 RMII 接口

MII 和 RMII 的一个明显区别在于其所需的信号数。MII 通常需要多达 18 个信号,RMII 接口则仅需要 9 个信号。

在 RMII 模式下,接收器和发射器信号的参考时钟为 REF_CLK在访问 PHY 和 MAC 时,REF_CLK 必须保持稳定。一般来说,根据您设计中 PHY 设备的特征,可通过以下三种方式生成 REF_CLK

  • 一些 PHY 芯片可以从其外部连接的 25 MHz 晶体振荡器中获取 REF_CLK (如图中的选项 a 所示)。对于此类芯片,请在 CONFIG_ETH_RMII_CLK_MODE 中选择 CONFIG_ETH_RMII_CLK_INPUT

  • 一些 PHY 芯片使用可以作为 MAC 端 REF_CLK 的外接 50 MHz 晶体振荡器或其他时钟源(如图中的选项 b 所示)。对于此类芯片,请同样在 CONFIG_ETH_RMII_CLK_MODE 中选择 CONFIG_ETH_RMII_CLK_INPUT

  • 一些 EMAC 控制器可以使用其内部的高精度 PLL 生成 REF_CLK (如图中的选项 c 所示)。此种情况下,请在 CONFIG_ETH_RMII_CLK_MODE 中选择 CONFIG_ETH_RMII_CLK_OUTPUT

备注

如上所述,REF_CLK 默认通过项目配置进行配置。然而,通过设置 eth_esp32_emac_config_t::interfaceeth_esp32_emac_config_t::clock_config,也可以实现在用户应用代码中覆盖该时钟。更多细节,请参见 emac_rmii_clock_mode_temac_rmii_clock_gpio_t

警告

如果配置 RMII 时钟模式为 CONFIG_ETH_RMII_CLK_OUTPUT,那么就可以使用 GPIO0 输出 REF_CLK 信号。更多细节,请参见 CONFIG_ETH_RMII_CLK_OUTPUT_GPIO0

值得一提的是,如果您在设计中并未使用 PSRAM,则 GPIO16 和 GPIO17 也可以用来输出参考时钟。更多细节,请参见 CONFIG_ETH_RMII_CLK_OUT_GPIO

如果配置 RMII 时钟模式为 CONFIG_ETH_RMII_CLK_INPUT,那么有且只有 GPIO0 可以用来输入 REF_CLK 信号。请注意, GPIO0 同时也是 ESP32 上一个重要的 strapping GPIO 管脚。如果 GPIO0 在上电时采样为低电平,ESP32 将进入下载模式,需进行手动复位重启系统。解决这个问题的方法是,在硬件中默认禁用 REF_CLK,从而避免 strapping 管脚在启动阶段受到其他信号的干扰。随后,再在以太网驱动安装阶段重新启用 REF_CLK

可以通过以下方法禁用 REF_CLK 信号:

  • 禁用或关闭晶体振荡器的电源(对应图中的选项 b)。

  • 强制复位 PHY 设备(对应图中的选项 a)。 此种方法并不适用于所有 PHY 设备,即便处于复位状态,某些 PHY 设备仍会向 GPIO0 输出信号。

无论选择哪种 RMII 时钟模式,都请确保硬件设计中 REF_CLK 的信号完整性! 信号线越短越好,并请保持信号线与 RF 设备和电感器元件的距离。

备注

ESP-IDF 只支持 RMII 接口(即在 Kconfig 选项 CONFIG_ETH_PHY_INTERFACE 中始终选择 CONFIG_ETH_PHY_INTERFACE_RMII)。

在数据平面使用的信号通过 MUX 连接至特定的 GPIO,这些信号无法配置至其他 GPIO。在控制平面使用的信号则可以通过 Matrix 矩阵路由到任何空闲 GPIO。相关的硬件设计示例,请参考 ESP32-Ethernet-Kit

根据您的以太网板设计,需要分别为 MAC 和 PHY 配置必要的参数,通过两者完成驱动程序的安装。

MAC 的相关配置可以在 eth_mac_config_t 中找到,具体包括:

MAC 的相关配置可以在 eth_phy_config_t 中找到,具体包括:

  • eth_phy_config_t::phy_addr:同一条 SMI 总线上可以存在多个 PHY 设备,所以有必要为各个 PHY 设备分配唯一地址。通常,这个地址是在硬件设计期间,通过拉高/拉低一些 PHY strapping 管脚来配置的。根据不同的以太网开发板,可配置值为 0 到 15。需注意,如果 SMI 总线上仅有一个 PHY 设备,将该值配置为 -1,即可使驱动程序自动检测 PHY 地址。

  • eth_phy_config_t::reset_timeout_ms:复位超时值,单位为毫秒。通常,PHY 复位应在 100 ms 内完成。

  • eth_phy_config_t::autonego_timeout_ms:自动协商超时值,单位为毫秒。以太网驱动程序会自动与对等的以太网节点进行协商,以确定双工和速度模式。此值通常取决于您电路板上 PHY 设备的性能。

  • eth_phy_config_t::reset_gpio_num:如果您的开发板同时将 PHY 复位管脚连接至了任意 GPIO 管脚,请使用该字段进行配置。否则,配置为 -1。

ESP-IDF 在宏 ETH_MAC_DEFAULT_CONFIGETH_PHY_DEFAULT_CONFIG 中为 MAC 和 PHY 提供了默认配置。

创建 MAC 和 PHY 实例

以太网驱动是以面向对象的方式实现的。对 MAC 和 PHY 的任何操作都应基于实例。

内部 EMAC + 外部 PHY

eth_mac_config_t mac_config = ETH_MAC_DEFAULT_CONFIG();                      // 应用默认的通用 MAC 配置
eth_esp32_emac_config_t esp32_emac_config = ETH_ESP32_EMAC_DEFAULT_CONFIG(); // 应用默认的供应商特定 MAC 配置
esp32_emac_config.smi_mdc_gpio_num = CONFIG_EXAMPLE_ETH_MDC_GPIO;            // 更改用于 MDC 信号的 GPIO
esp32_emac_config.smi_mdio_gpio_num = CONFIG_EXAMPLE_ETH_MDIO_GPIO;          // 更改用于 MDIO 信号的 GPIO
esp_eth_mac_t *mac = esp_eth_mac_new_esp32(&esp32_emac_config, &mac_config); // 创建 MAC 实例

eth_phy_config_t phy_config = ETH_PHY_DEFAULT_CONFIG();      // 应用默认的 PHY 配置
phy_config.phy_addr = CONFIG_EXAMPLE_ETH_PHY_ADDR;           // 根据开发板设计更改 PHY 地址
phy_config.reset_gpio_num = CONFIG_EXAMPLE_ETH_PHY_RST_GPIO; // 更改用于 PHY 复位的 GPIO
esp_eth_phy_t *phy = esp_eth_phy_new_ip101(&phy_config);     // 创建 PHY 实例
// ESP-IDF 为数种以太网 PHY 芯片驱动提供官方支持
// esp_eth_phy_t *phy = esp_eth_phy_new_rtl8201(&phy_config);
// esp_eth_phy_t *phy = esp_eth_phy_new_lan8720(&phy_config);
// esp_eth_phy_t *phy = esp_eth_phy_new_dp83848(&phy_config);

可选的运行时 MAC 时钟配置

可以通过用户应用程序代码,选择性配置 EMAC 中的 REF_CLK

eth_esp32_emac_config_t esp32_emac_config = ETH_ESP32_EMAC_DEFAULT_CONFIG(); // 应用默认的供应商特定 MAC 配置

// ...

esp32_emac_config.interface = EMAC_DATA_INTERFACE_RMII;                      // 更改 EMAC 数据接口
esp32_emac_config.clock_config.rmii.clock_mode = EMAC_CLK_OUT;               // 配置 EMAC REF_CLK 模式
esp32_emac_config.clock_config.rmii.clock_gpio = EMAC_CLK_OUT_GPIO;          // 配置用于输入/输出 EMAC REF_CLK 的 GPIO 编号
esp_eth_mac_t *mac = esp_eth_mac_new_esp32(&esp32_emac_config, &mac_config); // 创建 MAC 实例

SPI-Ethernet 模块

eth_mac_config_t mac_config = ETH_MAC_DEFAULT_CONFIG();      // 应用默认的通用 MAC 配置
eth_phy_config_t phy_config = ETH_PHY_DEFAULT_CONFIG();      // 应用默认的 PHY 配置
phy_config.phy_addr = CONFIG_EXAMPLE_ETH_PHY_ADDR;           // 根据开发板设计更改 PHY 地址
phy_config.reset_gpio_num = CONFIG_EXAMPLE_ETH_PHY_RST_GPIO; // 更改用于 PHY 复位的 GPIO
// 安装 GPIO 中断服务(因为 SPI-Ethernet 模块为中断驱动)
gpio_install_isr_service(0);
// 配置 SPI 总线
spi_device_handle_t spi_handle = NULL;
spi_bus_config_t buscfg = {
    .miso_io_num = CONFIG_EXAMPLE_ETH_SPI_MISO_GPIO,
    .mosi_io_num = CONFIG_EXAMPLE_ETH_SPI_MOSI_GPIO,
    .sclk_io_num = CONFIG_EXAMPLE_ETH_SPI_SCLK_GPIO,
    .quadwp_io_num = -1,
    .quadhd_io_num = -1,
};
ESP_ERROR_CHECK(spi_bus_initialize(CONFIG_EXAMPLE_ETH_SPI_HOST, &buscfg, 1));
// 配置 SPI 从机设备
spi_device_interface_config_t spi_devcfg = {
    .mode = 0,
    .clock_speed_hz = CONFIG_EXAMPLE_ETH_SPI_CLOCK_MHZ * 1000 * 1000,
    .spics_io_num = CONFIG_EXAMPLE_ETH_SPI_CS_GPIO,
    .queue_size = 20
};
/* dm9051 ethernet driver is based on spi driver */
eth_dm9051_config_t dm9051_config = ETH_DM9051_DEFAULT_CONFIG(CONFIG_EXAMPLE_ETH_SPI_HOST, &spi_devcfg);
dm9051_config.int_gpio_num = CONFIG_EXAMPLE_ETH_SPI_INT_GPIO;
esp_eth_mac_t *mac = esp_eth_mac_new_dm9051(&dm9051_config, &mac_config);
esp_eth_phy_t *phy = esp_eth_phy_new_dm9051(&phy_config);

备注

  • 当为 SPI-Ethernet 模块(例如 DM9051)创建 MAC 和 PHY 实例时,由于 PHY 是集成在模块中的,因此调用的实例创建函数的后缀须保持一致(例如 esp_eth_mac_new_dm9051esp_eth_phy_new_dm9051 搭配使用)。

  • 针对不同的以太网模块,或是为了满足特定 PCB 上的 SPI 时序,SPI 从机设备配置(即 spi_device_interface_config_t)可能略有不同。具体配置请查看模块规格以及 ESP-IDF 中的示例。

安装驱动程序

安装以太网驱动程序需要结合 MAC 和 PHY 实例,并在 esp_eth_config_t 中配置一些额外的高级选项(即不仅限于 MAC 或 PHY 的选项):

ESP-IDF 在宏 ETH_DEFAULT_CONFIG 中为安装驱动程序提供了一个默认配置。

esp_eth_config_t config = ETH_DEFAULT_CONFIG(mac, phy); // 应用默认驱动程序配置
esp_eth_handle_t eth_handle = NULL; // 驱动程序安装完毕后,将得到驱动程序的句柄
esp_eth_driver_install(&config, &eth_handle); // 安装驱动程序

以太网驱动程序包含事件驱动模型,该模型会向用户空间发送有用及重要的事件。安装以太网驱动程序之前,需要首先初始化事件循环。有关事件驱动编程的更多信息,请参考 ESP Event.

/** 以太网事件的事件处理程序 */
static void eth_event_handler(void *arg, esp_event_base_t event_base,
                              int32_t event_id, void *event_data)
{
    uint8_t mac_addr[6] = {0};
    /* 可从事件数据中获得以太网驱动句柄 */
    esp_eth_handle_t eth_handle = *(esp_eth_handle_t *)event_data;

    switch (event_id) {
    case ETHERNET_EVENT_CONNECTED:
        esp_eth_ioctl(eth_handle, ETH_CMD_G_MAC_ADDR, mac_addr);
        ESP_LOGI(TAG, "Ethernet Link Up");
        ESP_LOGI(TAG, "Ethernet HW Addr %02x:%02x:%02x:%02x:%02x:%02x",
                    mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5]);
        break;
    case ETHERNET_EVENT_DISCONNECTED:
        ESP_LOGI(TAG, "Ethernet Link Down");
        break;
    case ETHERNET_EVENT_START:
        ESP_LOGI(TAG, "Ethernet Started");
        break;
    case ETHERNET_EVENT_STOP:
        ESP_LOGI(TAG, "Ethernet Stopped");
        break;
    default:
        break;
    }
}

esp_event_loop_create_default(); // 创建一个在后台运行的默认事件循环
esp_event_handler_register(ETH_EVENT, ESP_EVENT_ANY_ID, &eth_event_handler, NULL); // 注册以太网事件处理程序(用于在发生 link up/down 等事件时,处理特定的用户相关内容)

启动以太网驱动程序

安装驱动程序后,可以立即启动以太网。

esp_eth_start(eth_handle); // 启动以太网驱动程序状态机

连接驱动程序至 TCP/IP 协议栈

现在,以太网驱动程序已经完成安装。但对应 OSI(开放式系统互连模型)来看,目前阶段仍然属于第二层(即数据链路层)。这意味着可以检测到 link up/down 事件,获得用户空间的 MAC 地址,但无法获得 IP 地址,当然也无法发送 HTTP 请求。ESP-IDF 中使用的 TCP/IP 协议栈是 LwIP,关于 LwIP 的更多信息,请参考 LwIP

要将以太网驱动程序连接至 TCP/IP 协议栈,需要以下三步:

  1. 为以太网驱动程序创建网络接口

  2. 将网络接口连接到以太网驱动程序

  3. 注册 IP 事件处理程序

有关网络接口的更多信息,请参考 Network Interface

/** IP_EVENT_ETH_GOT_IP 的事件处理程序 */
static void got_ip_event_handler(void *arg, esp_event_base_t event_base,
                                 int32_t event_id, void *event_data)
{
    ip_event_got_ip_t *event = (ip_event_got_ip_t *) event_data;
    const esp_netif_ip_info_t *ip_info = &event->ip_info;

    ESP_LOGI(TAG, "Ethernet Got IP Address");
    ESP_LOGI(TAG, "~~~~~~~~~~~");
    ESP_LOGI(TAG, "ETHIP:" IPSTR, IP2STR(&ip_info->ip));
    ESP_LOGI(TAG, "ETHMASK:" IPSTR, IP2STR(&ip_info->netmask));
    ESP_LOGI(TAG, "ETHGW:" IPSTR, IP2STR(&ip_info->gw));
    ESP_LOGI(TAG, "~~~~~~~~~~~");
}

esp_netif_init()); // 初始化 TCP/IP 网络接口(在应用程序中应仅调用一次)
esp_netif_config_t cfg = ESP_NETIF_DEFAULT_ETH(); // 应用以太网的默认网络接口配置
esp_netif_t *eth_netif = esp_netif_new(&cfg); // 为以太网驱动程序创建网络接口

esp_netif_attach(eth_netif, esp_eth_new_netif_glue(eth_handle)); // 将以太网驱动程序连接至 TCP/IP 协议栈
esp_event_handler_register(IP_EVENT, IP_EVENT_ETH_GOT_IP, &got_ip_event_handler, NULL); // 注册用户定义的 IP 事件处理程序
esp_eth_start(eth_handle); // 启动以太网驱动程序状态机

警告

推荐在完成整个以太网驱动和网络接口的初始化后,再注册用户定义的以太网/IP 事件处理程序,也就是把注册事件处理程序作为启动以太网驱动程序的最后一步。这样可以确保以太网驱动程序或网络接口将首先执行以太网/IP 事件,从而保证在执行用户定义的处理程序时,系统处于预期状态。

以太网驱动程序的杂项控制

以下功能只支持在安装以太网驱动程序后调用。

/* 获取 MAC 地址 */
uint8_t mac_addr[6];
memset(mac_addr, 0, sizeof(mac_addr));
esp_eth_ioctl(eth_handle, ETH_CMD_G_MAC_ADDR, mac_addr);
ESP_LOGI(TAG, "Ethernet MAC Address: %02x:%02x:%02x:%02x:%02x:%02x",
         mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5]);

/* 获取 PHY 地址 */
int phy_addr = -1;
esp_eth_ioctl(eth_handle, ETH_CMD_G_PHY_ADDR, &phy_addr);
ESP_LOGI(TAG, "Ethernet PHY Address: %d", phy_addr);

数据流量控制

受 RAM 大小限制,在网络拥堵时,MCU 上的以太网通常仅能处理有限数量的帧。发送站的数据传输速度可能快于对等端的接收能力。以太网数据流量控制机制允许接收节点向发送方发出信号,要求暂停传输,直到接收方跟上。这项功能是通过暂停帧实现的,该帧定义在 IEEE 802.3x 中。

暂停帧是一种特殊的以太网帧,用于携带暂停命令,其 EtherType 字段为 0x8808,控制操作码为 0x0001。只有配置为全双工操作的节点组可以发送暂停帧。当节点组希望暂停链路的另一端时,它会发送一个暂停帧到 48 位的保留组播地址 01-80-C2-00-00-01。暂停帧中也包括请求暂停的时间段,以两字节的整数形式发送,值的范围从 0 到 65535。

安装以太网驱动程序后,数据流量控制功能默认禁用,可以通过以下方式启用此功能:

bool flow_ctrl_enable = true;
esp_eth_ioctl(eth_handle, ETH_CMD_S_FLOW_CTRL, &flow_ctrl_enable);

需注意,暂停帧是在自动协商期间由 PHY 向对等端公布的。只有当链路的两边都支持暂停帧时,以太网驱动程序才会发送暂停帧。

应用示例

进阶操作

自定义 PHY 驱动程序

目前市面上已有多家 PHY 制造商提供了大量的芯片组合。ESP-IDF 现已支持数种 PHY 芯片,但是由于价格、功能、库存等原因,有时用户还是无法找到一款能满足其实际需求的芯片。

好在 IEEE 802.3 在其 22.2.4 管理功能部分对 EMAC 和 PHY 之间的管理接口进行了标准化。该部分定义了所谓的 ”MII 管理接口”规范,用于控制 PHY 和收集 PHY 的状态,还定义了一组管理寄存器来控制芯片行为、链接属性、自动协商配置等。在 ESP-IDF 中,这项基本的管理功能是由 esp_eth/src/esp_eth_phy_802_3.c 实现的,这也大大降低了创建新的自定义 PHY 芯片驱动的难度。

备注

由于一些 PHY 芯片可能不符合 IEEE 802.3 第 22.2.4 节的规定,所以请首先查看 PHY 数据手册。不过,就算芯片不符合规定,您依旧可以创建自定义 PHY 驱动程序,只是由于需要自行定义所有的 PHY 管理功能,这个过程将变得较为复杂。

ESP-IDF 以太网驱动程序所需的大部分 PHY 管理功能都已涵盖在 esp_eth/src/esp_eth_phy_802_3.c 中。不过对于以下几项,可能仍需针对不同芯片开发具体的管理功能:

  • 链接状态。此项总是由使用的具体芯片决定

  • 芯片初始化。即使不存在严格的限制,也应进行自定义,以确保使用的是符合预期的芯片

  • 芯片的具体功能配置

创建自定义 PHY 驱动程序的步骤:

  1. 请根据 PHY 数据手册,定义针对供应商的特定注册表布局。示例请参见 esp_eth/src/esp_eth_phy_ip101.c

  2. 准备衍生的 PHY 管理对象信息结构,该结构:

  3. 定义针对芯片的特定管理回调功能。

  4. 初始化 IEEE 802.3 父对象并重新分配针对芯片的特定管理回调功能。

实现新的自定义 PHY 驱动程序后,你可以通过 IDF组件管理中心 将驱动分享给其他用户。

API 参考

Header File

Header File

Functions

esp_err_t esp_eth_driver_install(const esp_eth_config_t *config, esp_eth_handle_t *out_hdl)

Install Ethernet driver.

参数
  • config[in] configuration of the Ethernet driver

  • out_hdl[out] handle of Ethernet driver

返回

  • ESP_OK: install esp_eth driver successfully

  • ESP_ERR_INVALID_ARG: install esp_eth driver failed because of some invalid argument

  • ESP_ERR_NO_MEM: install esp_eth driver failed because there’s no memory for driver

  • ESP_FAIL: install esp_eth driver failed because some other error occurred

esp_err_t esp_eth_driver_uninstall(esp_eth_handle_t hdl)

Uninstall Ethernet driver.

备注

It’s not recommended to uninstall Ethernet driver unless it won’t get used any more in application code. To uninstall Ethernet driver, you have to make sure, all references to the driver are released. Ethernet driver can only be uninstalled successfully when reference counter equals to one.

参数

hdl[in] handle of Ethernet driver

返回

  • ESP_OK: uninstall esp_eth driver successfully

  • ESP_ERR_INVALID_ARG: uninstall esp_eth driver failed because of some invalid argument

  • ESP_ERR_INVALID_STATE: uninstall esp_eth driver failed because it has more than one reference

  • ESP_FAIL: uninstall esp_eth driver failed because some other error occurred

esp_err_t esp_eth_start(esp_eth_handle_t hdl)

Start Ethernet driver ONLY in standalone mode (i.e. without TCP/IP stack)

备注

This API will start driver state machine and internal software timer (for checking link status).

参数

hdl[in] handle of Ethernet driver

返回

  • ESP_OK: start esp_eth driver successfully

  • ESP_ERR_INVALID_ARG: start esp_eth driver failed because of some invalid argument

  • ESP_ERR_INVALID_STATE: start esp_eth driver failed because driver has started already

  • ESP_FAIL: start esp_eth driver failed because some other error occurred

esp_err_t esp_eth_stop(esp_eth_handle_t hdl)

Stop Ethernet driver.

备注

This function does the oppsite operation of esp_eth_start.

参数

hdl[in] handle of Ethernet driver

返回

  • ESP_OK: stop esp_eth driver successfully

  • ESP_ERR_INVALID_ARG: stop esp_eth driver failed because of some invalid argument

  • ESP_ERR_INVALID_STATE: stop esp_eth driver failed because driver has not started yet

  • ESP_FAIL: stop esp_eth driver failed because some other error occurred

esp_err_t esp_eth_update_input_path(esp_eth_handle_t hdl, esp_err_t (*stack_input)(esp_eth_handle_t hdl, uint8_t *buffer, uint32_t length, void *priv), void *priv)

Update Ethernet data input path (i.e. specify where to pass the input buffer)

备注

After install driver, Ethernet still don’t know where to deliver the input buffer. In fact, this API registers a callback function which get invoked when Ethernet received new packets.

参数
  • hdl[in] handle of Ethernet driver

  • stack_input[in] function pointer, which does the actual process on incoming packets

  • priv[in] private resource, which gets passed to stack_input callback without any modification

返回

  • ESP_OK: update input path successfully

  • ESP_ERR_INVALID_ARG: update input path failed because of some invalid argument

  • ESP_FAIL: update input path failed because some other error occurred

esp_err_t esp_eth_transmit(esp_eth_handle_t hdl, void *buf, size_t length)

General Transmit.

参数
  • hdl[in] handle of Ethernet driver

  • buf[in] buffer of the packet to transfer

  • length[in] length of the buffer to transfer

返回

  • ESP_OK: transmit frame buffer successfully

  • ESP_ERR_INVALID_ARG: transmit frame buffer failed because of some invalid argument

  • ESP_ERR_INVALID_STATE: invalid driver state (e.i. driver is not started)

  • ESP_ERR_TIMEOUT: transmit frame buffer failed because HW was not get available in predefined period

  • ESP_FAIL: transmit frame buffer failed because some other error occurred

esp_err_t esp_eth_transmit_vargs(esp_eth_handle_t hdl, uint32_t argc, ...)

Special Transmit with variable number of arguments.

参数
  • hdl[in] handle of Ethernet driver

  • argc[in] number variable arguments

  • ... – variable arguments

返回

  • ESP_OK: transmit successfull

  • ESP_ERR_INVALID_STATE: invalid driver state (e.i. driver is not started)

  • ESP_ERR_TIMEOUT: transmit frame buffer failed because HW was not get available in predefined period

  • ESP_FAIL: transmit frame buffer failed because some other error occurred

esp_err_t esp_eth_ioctl(esp_eth_handle_t hdl, esp_eth_io_cmd_t cmd, void *data)

Misc IO function of Etherent driver.

The following common IO control commands are supported:

  • ETH_CMD_S_MAC_ADDR sets Ethernet interface MAC address. data argument is pointer to MAC address buffer with expected size of 6 bytes.

  • ETH_CMD_G_MAC_ADDR gets Ethernet interface MAC address. data argument is pointer to a buffer to which MAC address is to be copied. The buffer size must be at least 6 bytes.

  • ETH_CMD_S_PHY_ADDR sets PHY address in range of <0-31>. data argument is pointer to memory of uint32_t datatype from where the configuration option is read.

  • ETH_CMD_G_PHY_ADDR gets PHY address. data argument is pointer to memory of uint32_t datatype to which the PHY address is to be stored.

  • ETH_CMD_S_AUTONEGO enables or disables Ethernet link speed and duplex mode autonegotiation. data argument is pointer to memory of bool datatype from which the configuration option is read. Preconditions: Ethernet driver needs to be stopped.

  • ETH_CMD_G_AUTONEGO gets current configuration of the Ethernet link speed and duplex mode autonegotiation. data argument is pointer to memory of bool datatype to which the current configuration is to be stored.

  • ETH_CMD_S_SPEED sets the Ethernet link speed. data argument is pointer to memory of eth_speed_t datatype from which the configuration option is read. Preconditions: Ethernet driver needs to be stopped and auto-negotiation disabled.

  • ETH_CMD_G_SPEED gets current Ethernet link speed. data argument is pointer to memory of eth_speed_t datatype to which the speed is to be stored.

  • ETH_CMD_S_PROMISCUOUS sets/resets Ethernet interface promiscuous mode. data argument is pointer to memory of bool datatype from which the configuration option is read.

  • ETH_CMD_S_FLOW_CTRL sets/resets Ethernet interface flow control. data argument is pointer to memory of bool datatype from which the configuration option is read.

  • ETH_CMD_S_DUPLEX_MODE sets the Ethernet duplex mode. data argument is pointer to memory of eth_duplex_t datatype from which the configuration option is read. Preconditions: Ethernet driver needs to be stopped and auto-negotiation disabled.

  • ETH_CMD_G_DUPLEX_MODE gets current Ethernet link duplex mode. data argument is pointer to memory of eth_duplex_t datatype to which the duplex mode is to be stored.

  • ETH_CMD_S_PHY_LOOPBACK sets/resets PHY to/from loopback mode. data argument is pointer to memory of bool datatype from which the configuration option is read.

  • Note that additional control commands may be available for specific MAC or PHY chips. Please consult specific MAC or PHY documentation or driver code.

参数
  • hdl[in] handle of Ethernet driver

  • cmd[in] IO control command

  • data[inout] address of data for set command or address where to store the data when used with get command

返回

  • ESP_OK: process io command successfully

  • ESP_ERR_INVALID_ARG: process io command failed because of some invalid argument

  • ESP_FAIL: process io command failed because some other error occurred

  • ESP_ERR_NOT_SUPPORTED: requested feature is not supported

esp_err_t esp_eth_increase_reference(esp_eth_handle_t hdl)

Increase Ethernet driver reference.

备注

Ethernet driver handle can be obtained by os timer, netif, etc. It’s dangerous when thread A is using Ethernet but thread B uninstall the driver. Using reference counter can prevent such risk, but care should be taken, when you obtain Ethernet driver, this API must be invoked so that the driver won’t be uninstalled during your using time.

参数

hdl[in] handle of Ethernet driver

返回

  • ESP_OK: increase reference successfully

  • ESP_ERR_INVALID_ARG: increase reference failed because of some invalid argument

esp_err_t esp_eth_decrease_reference(esp_eth_handle_t hdl)

Decrease Ethernet driver reference.

参数

hdl[in] handle of Ethernet driver

返回

  • ESP_OK: increase reference successfully

  • ESP_ERR_INVALID_ARG: increase reference failed because of some invalid argument

Structures

struct esp_eth_config_t

Configuration of Ethernet driver.

Public Members

esp_eth_mac_t *mac

Ethernet MAC object.

esp_eth_phy_t *phy

Ethernet PHY object.

Period time of checking Ethernet link status.

esp_err_t (*stack_input)(esp_eth_handle_t eth_handle, uint8_t *buffer, uint32_t length, void *priv)

Input frame buffer to user’s stack.

Param eth_handle

[in] handle of Ethernet driver

Param buffer

[in] frame buffer that will get input to upper stack

Param length

[in] length of the frame buffer

Return

  • ESP_OK: input frame buffer to upper stack successfully

  • ESP_FAIL: error occurred when inputting buffer to upper stack

esp_err_t (*on_lowlevel_init_done)(esp_eth_handle_t eth_handle)

Callback function invoked when lowlevel initialization is finished.

Param eth_handle

[in] handle of Ethernet driver

Return

  • ESP_OK: process extra lowlevel initialization successfully

  • ESP_FAIL: error occurred when processing extra lowlevel initialization

esp_err_t (*on_lowlevel_deinit_done)(esp_eth_handle_t eth_handle)

Callback function invoked when lowlevel deinitialization is finished.

Param eth_handle

[in] handle of Ethernet driver

Return

  • ESP_OK: process extra lowlevel deinitialization successfully

  • ESP_FAIL: error occurred when processing extra lowlevel deinitialization

esp_err_t (*read_phy_reg)(esp_eth_handle_t eth_handle, uint32_t phy_addr, uint32_t phy_reg, uint32_t *reg_value)

Read PHY register.

备注

Usually the PHY register read/write function is provided by MAC (SMI interface), but if the PHY device is managed by other interface (e.g. I2C), then user needs to implement the corresponding read/write. Setting this to NULL means your PHY device is managed by MAC’s SMI interface.

Param eth_handle

[in] handle of Ethernet driver

Param phy_addr

[in] PHY chip address (0~31)

Param phy_reg

[in] PHY register index code

Param reg_value

[out] PHY register value

Return

  • ESP_OK: read PHY register successfully

  • ESP_ERR_INVALID_ARG: read PHY register failed because of invalid argument

  • ESP_ERR_TIMEOUT: read PHY register failed because of timeout

  • ESP_FAIL: read PHY register failed because some other error occurred

esp_err_t (*write_phy_reg)(esp_eth_handle_t eth_handle, uint32_t phy_addr, uint32_t phy_reg, uint32_t reg_value)

Write PHY register.

备注

Usually the PHY register read/write function is provided by MAC (SMI interface), but if the PHY device is managed by other interface (e.g. I2C), then user needs to implement the corresponding read/write. Setting this to NULL means your PHY device is managed by MAC’s SMI interface.

Param eth_handle

[in] handle of Ethernet driver

Param phy_addr

[in] PHY chip address (0~31)

Param phy_reg

[in] PHY register index code

Param reg_value

[in] PHY register value

Return

  • ESP_OK: write PHY register successfully

  • ESP_ERR_INVALID_ARG: read PHY register failed because of invalid argument

  • ESP_ERR_TIMEOUT: write PHY register failed because of timeout

  • ESP_FAIL: write PHY register failed because some other error occurred

struct esp_eth_phy_reg_rw_data_t

Data structure to Read/Write PHY register via ioctl API.

Public Members

uint32_t reg_addr

PHY register address

uint32_t *reg_value_p

Pointer to a memory where the register value is read/written

Macros

ETH_DEFAULT_CONFIG(emac, ephy)

Default configuration for Ethernet driver.

Type Definitions

typedef void *esp_eth_handle_t

Handle of Ethernet driver.

Enumerations

enum esp_eth_io_cmd_t

Command list for ioctl API.

Values:

enumerator ETH_CMD_G_MAC_ADDR

Get MAC address

enumerator ETH_CMD_S_MAC_ADDR

Set MAC address

enumerator ETH_CMD_G_PHY_ADDR

Get PHY address

enumerator ETH_CMD_S_PHY_ADDR

Set PHY address

enumerator ETH_CMD_G_AUTONEGO

Get PHY Auto Negotiation

enumerator ETH_CMD_S_AUTONEGO

Set PHY Auto Negotiation

enumerator ETH_CMD_G_SPEED

Get Speed

enumerator ETH_CMD_S_SPEED

Set Speed

enumerator ETH_CMD_S_PROMISCUOUS

Set promiscuous mode

enumerator ETH_CMD_S_FLOW_CTRL

Set flow control

enumerator ETH_CMD_G_DUPLEX_MODE

Get Duplex mode

enumerator ETH_CMD_S_DUPLEX_MODE

Set Duplex mode

enumerator ETH_CMD_S_PHY_LOOPBACK

Set PHY loopback

enumerator ETH_CMD_READ_PHY_REG

Read PHY register

enumerator ETH_CMD_WRITE_PHY_REG

Write PHY register

enumerator ETH_CMD_CUSTOM_MAC_CMDS
enumerator ETH_CMD_CUSTOM_PHY_CMDS

Header File

Structures

struct esp_eth_mediator_s

Ethernet mediator.

Public Members

esp_err_t (*phy_reg_read)(esp_eth_mediator_t *eth, uint32_t phy_addr, uint32_t phy_reg, uint32_t *reg_value)

Read PHY register.

Param eth

[in] mediator of Ethernet driver

Param phy_addr

[in] PHY Chip address (0~31)

Param phy_reg

[in] PHY register index code

Param reg_value

[out] PHY register value

Return

  • ESP_OK: read PHY register successfully

  • ESP_FAIL: read PHY register failed because some error occurred

esp_err_t (*phy_reg_write)(esp_eth_mediator_t *eth, uint32_t phy_addr, uint32_t phy_reg, uint32_t reg_value)

Write PHY register.

Param eth

[in] mediator of Ethernet driver

Param phy_addr

[in] PHY Chip address (0~31)

Param phy_reg

[in] PHY register index code

Param reg_value

[in] PHY register value

Return

  • ESP_OK: write PHY register successfully

  • ESP_FAIL: write PHY register failed because some error occurred

esp_err_t (*stack_input)(esp_eth_mediator_t *eth, uint8_t *buffer, uint32_t length)

Deliver packet to upper stack.

Param eth

[in] mediator of Ethernet driver

Param buffer

[in] packet buffer

Param length

[in] length of the packet

Return

  • ESP_OK: deliver packet to upper stack successfully

  • ESP_FAIL: deliver packet failed because some error occurred

esp_err_t (*on_state_changed)(esp_eth_mediator_t *eth, esp_eth_state_t state, void *args)

Callback on Ethernet state changed.

Param eth

[in] mediator of Ethernet driver

Param state

[in] new state

Param args

[in] optional argument for the new state

Return

  • ESP_OK: process the new state successfully

  • ESP_FAIL: process the new state failed because some error occurred

Type Definitions

typedef struct esp_eth_mediator_s esp_eth_mediator_t

Ethernet mediator.

Enumerations

enum esp_eth_state_t

Ethernet driver state.

Values:

enumerator ETH_STATE_LLINIT

Lowlevel init done

enumerator ETH_STATE_DEINIT

Deinit done

enumerator ETH_STATE_LINK

Link status changed

enumerator ETH_STATE_SPEED

Speed updated

enumerator ETH_STATE_DUPLEX

Duplex updated

enumerator ETH_STATE_PAUSE

Pause ability updated

enum eth_event_t

Ethernet event declarations.

Values:

enumerator ETHERNET_EVENT_START

Ethernet driver start

enumerator ETHERNET_EVENT_STOP

Ethernet driver stop

enumerator ETHERNET_EVENT_CONNECTED

Ethernet got a valid link

enumerator ETHERNET_EVENT_DISCONNECTED

Ethernet lost a valid link

Header File

Functions

esp_eth_mac_t *esp_eth_mac_new_esp32(const eth_esp32_emac_config_t *esp32_config, const eth_mac_config_t *config)

Create ESP32 Ethernet MAC instance.

参数
  • esp32_config – EMAC specific configuration

  • config – Ethernet MAC configuration

返回

  • instance: create MAC instance successfully

  • NULL: create MAC instance failed because some error occurred

Unions

union eth_mac_clock_config_t
#include <esp_eth_mac.h>

Ethernet MAC Clock Configuration.

Public Members

struct eth_mac_clock_config_t::[anonymous] mii

EMAC MII Clock Configuration

emac_rmii_clock_mode_t clock_mode

RMII Clock Mode Configuration

emac_rmii_clock_gpio_t clock_gpio

RMII Clock GPIO Configuration

struct eth_mac_clock_config_t::[anonymous] rmii

EMAC RMII Clock Configuration

Structures

struct esp_eth_mac_s

Ethernet MAC.

Public Members

esp_err_t (*set_mediator)(esp_eth_mac_t *mac, esp_eth_mediator_t *eth)

Set mediator for Ethernet MAC.

Param mac

[in] Ethernet MAC instance

Param eth

[in] Ethernet mediator

Return

  • ESP_OK: set mediator for Ethernet MAC successfully

  • ESP_ERR_INVALID_ARG: set mediator for Ethernet MAC failed because of invalid argument

esp_err_t (*init)(esp_eth_mac_t *mac)

Initialize Ethernet MAC.

Param mac

[in] Ethernet MAC instance

Return

  • ESP_OK: initialize Ethernet MAC successfully

  • ESP_ERR_TIMEOUT: initialize Ethernet MAC failed because of timeout

  • ESP_FAIL: initialize Ethernet MAC failed because some other error occurred

esp_err_t (*deinit)(esp_eth_mac_t *mac)

Deinitialize Ethernet MAC.

Param mac

[in] Ethernet MAC instance

Return

  • ESP_OK: deinitialize Ethernet MAC successfully

  • ESP_FAIL: deinitialize Ethernet MAC failed because some error occurred

esp_err_t (*start)(esp_eth_mac_t *mac)

Start Ethernet MAC.

Param mac

[in] Ethernet MAC instance

Return

  • ESP_OK: start Ethernet MAC successfully

  • ESP_FAIL: start Ethernet MAC failed because some other error occurred

esp_err_t (*stop)(esp_eth_mac_t *mac)

Stop Ethernet MAC.

Param mac

[in] Ethernet MAC instance

Return

  • ESP_OK: stop Ethernet MAC successfully

  • ESP_FAIL: stop Ethernet MAC failed because some error occurred

esp_err_t (*transmit)(esp_eth_mac_t *mac, uint8_t *buf, uint32_t length)

Transmit packet from Ethernet MAC.

备注

Returned error codes may differ for each specific MAC chip.

Param mac

[in] Ethernet MAC instance

Param buf

[in] packet buffer to transmit

Param length

[in] length of packet

Return

  • ESP_OK: transmit packet successfully

  • ESP_ERR_INVALID_SIZE: number of actually sent bytes differs to expected

  • ESP_FAIL: transmit packet failed because some other error occurred

esp_err_t (*transmit_vargs)(esp_eth_mac_t *mac, uint32_t argc, va_list args)

Transmit packet from Ethernet MAC constructed with special parameters at Layer2.

备注

Typical intended use case is to make possible to construct a frame from multiple higher layer buffers without a need of buffer reallocations. However, other use cases are not limited.

备注

Returned error codes may differ for each specific MAC chip.

Param mac

[in] Ethernet MAC instance

Param argc

[in] number variable arguments

Param args

[in] variable arguments

Return

  • ESP_OK: transmit packet successfully

  • ESP_ERR_INVALID_SIZE: number of actually sent bytes differs to expected

  • ESP_FAIL: transmit packet failed because some other error occurred

esp_err_t (*receive)(esp_eth_mac_t *mac, uint8_t *buf, uint32_t *length)

Receive packet from Ethernet MAC.

备注

Memory of buf is allocated in the Layer2, make sure it get free after process.

备注

Before this function got invoked, the value of “length” should set by user, equals the size of buffer. After the function returned, the value of “length” means the real length of received data.

Param mac

[in] Ethernet MAC instance

Param buf

[out] packet buffer which will preserve the received frame

Param length

[out] length of the received packet

Return

  • ESP_OK: receive packet successfully

  • ESP_ERR_INVALID_ARG: receive packet failed because of invalid argument

  • ESP_ERR_INVALID_SIZE: input buffer size is not enough to hold the incoming data. in this case, value of returned “length” indicates the real size of incoming data.

  • ESP_FAIL: receive packet failed because some other error occurred

esp_err_t (*read_phy_reg)(esp_eth_mac_t *mac, uint32_t phy_addr, uint32_t phy_reg, uint32_t *reg_value)

Read PHY register.

Param mac

[in] Ethernet MAC instance

Param phy_addr

[in] PHY chip address (0~31)

Param phy_reg

[in] PHY register index code

Param reg_value

[out] PHY register value

Return

  • ESP_OK: read PHY register successfully

  • ESP_ERR_INVALID_ARG: read PHY register failed because of invalid argument

  • ESP_ERR_INVALID_STATE: read PHY register failed because of wrong state of MAC

  • ESP_ERR_TIMEOUT: read PHY register failed because of timeout

  • ESP_FAIL: read PHY register failed because some other error occurred

esp_err_t (*write_phy_reg)(esp_eth_mac_t *mac, uint32_t phy_addr, uint32_t phy_reg, uint32_t reg_value)

Write PHY register.

Param mac

[in] Ethernet MAC instance

Param phy_addr

[in] PHY chip address (0~31)

Param phy_reg

[in] PHY register index code

Param reg_value

[in] PHY register value

Return

  • ESP_OK: write PHY register successfully

  • ESP_ERR_INVALID_STATE: write PHY register failed because of wrong state of MAC

  • ESP_ERR_TIMEOUT: write PHY register failed because of timeout

  • ESP_FAIL: write PHY register failed because some other error occurred

esp_err_t (*set_addr)(esp_eth_mac_t *mac, uint8_t *addr)

Set MAC address.

Param mac

[in] Ethernet MAC instance

Param addr

[in] MAC address

Return

  • ESP_OK: set MAC address successfully

  • ESP_ERR_INVALID_ARG: set MAC address failed because of invalid argument

  • ESP_FAIL: set MAC address failed because some other error occurred

esp_err_t (*get_addr)(esp_eth_mac_t *mac, uint8_t *addr)

Get MAC address.

Param mac

[in] Ethernet MAC instance

Param addr

[out] MAC address

Return

  • ESP_OK: get MAC address successfully

  • ESP_ERR_INVALID_ARG: get MAC address failed because of invalid argument

  • ESP_FAIL: get MAC address failed because some other error occurred

esp_err_t (*set_speed)(esp_eth_mac_t *mac, eth_speed_t speed)

Set speed of MAC.

Param ma:c

[in] Ethernet MAC instance

Param speed

[in] MAC speed

Return

  • ESP_OK: set MAC speed successfully

  • ESP_ERR_INVALID_ARG: set MAC speed failed because of invalid argument

  • ESP_FAIL: set MAC speed failed because some other error occurred

esp_err_t (*set_duplex)(esp_eth_mac_t *mac, eth_duplex_t duplex)

Set duplex mode of MAC.

Param mac

[in] Ethernet MAC instance

Param duplex

[in] MAC duplex

Return

  • ESP_OK: set MAC duplex mode successfully

  • ESP_ERR_INVALID_ARG: set MAC duplex failed because of invalid argument

  • ESP_FAIL: set MAC duplex failed because some other error occurred

esp_err_t (*set_link)(esp_eth_mac_t *mac, eth_link_t link)

Set link status of MAC.

Param mac

[in] Ethernet MAC instance

Param link

[in] Link status

Return

  • ESP_OK: set link status successfully

  • ESP_ERR_INVALID_ARG: set link status failed because of invalid argument

  • ESP_FAIL: set link status failed because some other error occurred

esp_err_t (*set_promiscuous)(esp_eth_mac_t *mac, bool enable)

Set promiscuous of MAC.

Param mac

[in] Ethernet MAC instance

Param enable

[in] set true to enable promiscuous mode; set false to disable promiscuous mode

Return

  • ESP_OK: set promiscuous mode successfully

  • ESP_FAIL: set promiscuous mode failed because some error occurred

esp_err_t (*enable_flow_ctrl)(esp_eth_mac_t *mac, bool enable)

Enable flow control on MAC layer or not.

Param mac

[in] Ethernet MAC instance

Param enable

[in] set true to enable flow control; set false to disable flow control

Return

  • ESP_OK: set flow control successfully

  • ESP_FAIL: set flow control failed because some error occurred

esp_err_t (*set_peer_pause_ability)(esp_eth_mac_t *mac, uint32_t ability)

Set the PAUSE ability of peer node.

Param mac

[in] Ethernet MAC instance

Param ability

[in] zero indicates that pause function is supported by link partner; non-zero indicates that pause function is not supported by link partner

Return

  • ESP_OK: set peer pause ability successfully

  • ESP_FAIL: set peer pause ability failed because some error occurred

esp_err_t (*custom_ioctl)(esp_eth_mac_t *mac, uint32_t cmd, void *data)

Custom IO function of MAC driver. This function is intended to extend common options of esp_eth_ioctl to cover specifics of MAC chip.

备注

This function may not be assigned when the MAC chip supports only most common set of configuration options.

Param mac

[in] Ethernet MAC instance

Param cmd

[in] IO control command

Param data

[inout] address of data for set command or address where to store the data when used with get command

Return

  • ESP_OK: process io command successfully

  • ESP_ERR_INVALID_ARG: process io command failed because of some invalid argument

  • ESP_FAIL: process io command failed because some other error occurred

  • ESP_ERR_NOT_SUPPORTED: requested feature is not supported

esp_err_t (*del)(esp_eth_mac_t *mac)

Free memory of Ethernet MAC.

Param mac

[in] Ethernet MAC instance

Return

  • ESP_OK: free Ethernet MAC instance successfully

  • ESP_FAIL: free Ethernet MAC instance failed because some error occurred

struct eth_mac_config_t

Configuration of Ethernet MAC object.

Public Members

uint32_t sw_reset_timeout_ms

Software reset timeout value (Unit: ms)

uint32_t rx_task_stack_size

Stack size of the receive task

uint32_t rx_task_prio

Priority of the receive task

uint32_t flags

Flags that specify extra capability for mac driver

struct eth_esp32_emac_config_t

EMAC specific configuration.

Public Members

int smi_mdc_gpio_num

SMI MDC GPIO number, set to -1 could bypass the SMI GPIO configuration

int smi_mdio_gpio_num

SMI MDIO GPIO number, set to -1 could bypass the SMI GPIO configuration

eth_data_interface_t interface

EMAC Data interface to PHY (MII/RMII)

eth_mac_clock_config_t clock_config

EMAC Interface clock configuration

eth_mac_dma_burst_len_t dma_burst_len

EMAC DMA burst length for both Tx and Rx

Macros

ETH_MAC_FLAG_WORK_WITH_CACHE_DISABLE

MAC driver can work when cache is disabled

ETH_MAC_FLAG_PIN_TO_CORE

Pin MAC task to the CPU core where driver installation happened

ETH_MAC_DEFAULT_CONFIG()

Default configuration for Ethernet MAC object.

ETH_ESP32_EMAC_DEFAULT_CONFIG()

Default ESP32’s EMAC specific configuration.

Type Definitions

typedef struct esp_eth_mac_s esp_eth_mac_t

Ethernet MAC.

Enumerations

enum emac_rmii_clock_mode_t

RMII Clock Mode Options.

Values:

enumerator EMAC_CLK_DEFAULT

Default values configured using Kconfig are going to be used when “Default” selected.

enumerator EMAC_CLK_EXT_IN

Input RMII Clock from external. EMAC Clock GPIO number needs to be configured when this option is selected.

备注

MAC will get RMII clock from outside. Note that ESP32 only supports GPIO0 to input the RMII clock.

enumerator EMAC_CLK_OUT

Output RMII Clock from internal APLL Clock. EMAC Clock GPIO number needs to be configured when this option is selected.

enum emac_rmii_clock_gpio_t

RMII Clock GPIO number Options.

Values:

enumerator EMAC_CLK_IN_GPIO

MAC will get RMII clock from outside at this GPIO.

备注

ESP32 only supports GPIO0 to input the RMII clock.

enumerator EMAC_APPL_CLK_OUT_GPIO

Output RMII Clock from internal APLL Clock available at GPIO0.

备注

GPIO0 can be set to output a pre-divided PLL clock (test only!). Enabling this option will configure GPIO0 to output a 50MHz clock. In fact this clock doesn’t have directly relationship with EMAC peripheral. Sometimes this clock won’t work well with your PHY chip. You might need to add some extra devices after GPIO0 (e.g. inverter). Note that outputting RMII clock on GPIO0 is an experimental practice. If you want the Ethernet to work with WiFi, don’t select GPIO0 output mode for stability.

enumerator EMAC_CLK_OUT_GPIO

Output RMII Clock from internal APLL Clock available at GPIO16.

enumerator EMAC_CLK_OUT_180_GPIO

Inverted Output RMII Clock from internal APLL Clock available at GPIO17.

Header File

Functions

esp_eth_phy_t *esp_eth_phy_new_ip101(const eth_phy_config_t *config)

Create a PHY instance of IP101.

参数

config[in] configuration of PHY

返回

  • instance: create PHY instance successfully

  • NULL: create PHY instance failed because some error occurred

esp_eth_phy_t *esp_eth_phy_new_rtl8201(const eth_phy_config_t *config)

Create a PHY instance of RTL8201.

参数

config[in] configuration of PHY

返回

  • instance: create PHY instance successfully

  • NULL: create PHY instance failed because some error occurred

esp_eth_phy_t *esp_eth_phy_new_lan87xx(const eth_phy_config_t *config)

Create a PHY instance of LAN87xx.

参数

config[in] configuration of PHY

返回

  • instance: create PHY instance successfully

  • NULL: create PHY instance failed because some error occurred

esp_eth_phy_t *esp_eth_phy_new_dp83848(const eth_phy_config_t *config)

Create a PHY instance of DP83848.

参数

config[in] configuration of PHY

返回

  • instance: create PHY instance successfully

  • NULL: create PHY instance failed because some error occurred

esp_eth_phy_t *esp_eth_phy_new_ksz80xx(const eth_phy_config_t *config)

Create a PHY instance of KSZ80xx.

The phy model from the KSZ80xx series is detected automatically. If the driver is unable to detect a supported model, NULL is returned.

Currently, the following models are supported: KSZ8001, KSZ8021, KSZ8031, KSZ8041, KSZ8051, KSZ8061, KSZ8081, KSZ8091

参数

config[in] configuration of PHY

返回

  • instance: create PHY instance successfully

  • NULL: create PHY instance failed because some error occurred

Structures

struct esp_eth_phy_s

Ethernet PHY.

Public Members

esp_err_t (*set_mediator)(esp_eth_phy_t *phy, esp_eth_mediator_t *mediator)

Set mediator for PHY.

Param phy

[in] Ethernet PHY instance

Param mediator

[in] mediator of Ethernet driver

Return

  • ESP_OK: set mediator for Ethernet PHY instance successfully

  • ESP_ERR_INVALID_ARG: set mediator for Ethernet PHY instance failed because of some invalid arguments

esp_err_t (*reset)(esp_eth_phy_t *phy)

Software Reset Ethernet PHY.

Param phy

[in] Ethernet PHY instance

Return

  • ESP_OK: reset Ethernet PHY successfully

  • ESP_FAIL: reset Ethernet PHY failed because some error occurred

esp_err_t (*reset_hw)(esp_eth_phy_t *phy)

Hardware Reset Ethernet PHY.

备注

Hardware reset is mostly done by pull down and up PHY’s nRST pin

Param phy

[in] Ethernet PHY instance

Return

  • ESP_OK: reset Ethernet PHY successfully

  • ESP_FAIL: reset Ethernet PHY failed because some error occurred

esp_err_t (*init)(esp_eth_phy_t *phy)

Initialize Ethernet PHY.

Param phy

[in] Ethernet PHY instance

Return

  • ESP_OK: initialize Ethernet PHY successfully

  • ESP_FAIL: initialize Ethernet PHY failed because some error occurred

esp_err_t (*deinit)(esp_eth_phy_t *phy)

Deinitialize Ethernet PHY.

Param phy

[in] Ethernet PHY instance

Return

  • ESP_OK: deinitialize Ethernet PHY successfully

  • ESP_FAIL: deinitialize Ethernet PHY failed because some error occurred

esp_err_t (*autonego_ctrl)(esp_eth_phy_t *phy, eth_phy_autoneg_cmd_t cmd, bool *autonego_en_stat)

Configure auto negotiation.

Param phy

[in] Ethernet PHY instance

Param cmd

[in] Configuration command, it is possible to Enable (restart), Disable or get current status of PHY auto negotiation

Param autonego_en_stat

[out] Address where to store current status of auto negotiation configuration

Return

  • ESP_OK: restart auto negotiation successfully

  • ESP_FAIL: restart auto negotiation failed because some error occurred

  • ESP_ERR_INVALID_ARG: invalid command

esp_err_t (*get_link)(esp_eth_phy_t *phy)

Get Ethernet PHY link status.

Param phy

[in] Ethernet PHY instance

Return

  • ESP_OK: get Ethernet PHY link status successfully

  • ESP_FAIL: get Ethernet PHY link status failed because some error occurred

esp_err_t (*set_link)(esp_eth_phy_t *phy, eth_link_t link)

Set Ethernet PHY link status.

Param phy

[in] Ethernet PHY instance

Param link

[in] new link status

Return

  • ESP_OK: set Ethernet PHY link status successfully

  • ESP_FAIL: set Ethernet PHY link status failed because some error occurred

esp_err_t (*pwrctl)(esp_eth_phy_t *phy, bool enable)

Power control of Ethernet PHY.

Param phy

[in] Ethernet PHY instance

Param enable

[in] set true to power on Ethernet PHY; ser false to power off Ethernet PHY

Return

  • ESP_OK: control Ethernet PHY power successfully

  • ESP_FAIL: control Ethernet PHY power failed because some error occurred

esp_err_t (*set_addr)(esp_eth_phy_t *phy, uint32_t addr)

Set PHY chip address.

Param phy

[in] Ethernet PHY instance

Param addr

[in] PHY chip address

Return

  • ESP_OK: set Ethernet PHY address successfully

  • ESP_FAIL: set Ethernet PHY address failed because some error occurred

esp_err_t (*get_addr)(esp_eth_phy_t *phy, uint32_t *addr)

Get PHY chip address.

Param phy

[in] Ethernet PHY instance

Param addr

[out] PHY chip address

Return

  • ESP_OK: get Ethernet PHY address successfully

  • ESP_ERR_INVALID_ARG: get Ethernet PHY address failed because of invalid argument

esp_err_t (*advertise_pause_ability)(esp_eth_phy_t *phy, uint32_t ability)

Advertise pause function supported by MAC layer.

Param phy

[in] Ethernet PHY instance

Param addr

[out] Pause ability

Return

  • ESP_OK: Advertise pause ability successfully

  • ESP_ERR_INVALID_ARG: Advertise pause ability failed because of invalid argument

esp_err_t (*loopback)(esp_eth_phy_t *phy, bool enable)

Sets the PHY to loopback mode.

Param phy

[in] Ethernet PHY instance

Param enable

[in] enables or disables PHY loopback

Return

  • ESP_OK: PHY instance loopback mode has been configured successfully

  • ESP_FAIL: PHY instance loopback configuration failed because some error occurred

esp_err_t (*set_speed)(esp_eth_phy_t *phy, eth_speed_t speed)

Sets PHY speed mode.

备注

Autonegotiation feature needs to be disabled prior to calling this function for the new setting to be applied

Param phy

[in] Ethernet PHY instance

Param speed

[in] Speed mode to be set

Return

  • ESP_OK: PHY instance speed mode has been configured successfully

  • ESP_FAIL: PHY instance speed mode configuration failed because some error occurred

esp_err_t (*set_duplex)(esp_eth_phy_t *phy, eth_duplex_t duplex)

Sets PHY duplex mode.

备注

Autonegotiation feature needs to be disabled prior to calling this function for the new setting to be applied

Param phy

[in] Ethernet PHY instance

Param duplex

[in] Duplex mode to be set

Return

  • ESP_OK: PHY instance duplex mode has been configured successfully

  • ESP_FAIL: PHY instance duplex mode configuration failed because some error occurred

esp_err_t (*custom_ioctl)(esp_eth_phy_t *phy, uint32_t cmd, void *data)

Custom IO function of PHY driver. This function is intended to extend common options of esp_eth_ioctl to cover specifics of PHY chip.

备注

This function may not be assigned when the PHY chip supports only most common set of configuration options.

Param phy

[in] Ethernet PHY instance

Param cmd

[in] IO control command

Param data

[inout] address of data for set command or address where to store the data when used with get command

Return

  • ESP_OK: process io command successfully

  • ESP_ERR_INVALID_ARG: process io command failed because of some invalid argument

  • ESP_FAIL: process io command failed because some other error occurred

  • ESP_ERR_NOT_SUPPORTED: requested feature is not supported

esp_err_t (*del)(esp_eth_phy_t *phy)

Free memory of Ethernet PHY instance.

Param phy

[in] Ethernet PHY instance

Return

  • ESP_OK: free PHY instance successfully

  • ESP_FAIL: free PHY instance failed because some error occurred

struct eth_phy_config_t

Ethernet PHY configuration.

Public Members

int32_t phy_addr

PHY address, set -1 to enable PHY address detection at initialization stage

uint32_t reset_timeout_ms

Reset timeout value (Unit: ms)

uint32_t autonego_timeout_ms

Auto-negotiation timeout value (Unit: ms)

int reset_gpio_num

Reset GPIO number, -1 means no hardware reset

Macros

ESP_ETH_PHY_ADDR_AUTO
ETH_PHY_DEFAULT_CONFIG()

Default configuration for Ethernet PHY object.

Type Definitions

typedef struct esp_eth_phy_s esp_eth_phy_t

Ethernet PHY.

Enumerations

enum eth_phy_autoneg_cmd_t

Auto-negotiation controll commands.

Values:

enumerator ESP_ETH_PHY_AUTONEGO_RESTART
enumerator ESP_ETH_PHY_AUTONEGO_EN
enumerator ESP_ETH_PHY_AUTONEGO_DIS
enumerator ESP_ETH_PHY_AUTONEGO_G_STAT

Header File

Functions

esp_err_t esp_eth_phy_802_3_set_mediator(phy_802_3_t *phy_802_3, esp_eth_mediator_t *eth)

Set Ethernet mediator.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • eth – Ethernet mediator pointer

返回

  • ESP_OK: Ethermet mediator set successfuly

  • ESP_ERR_INVALID_ARG: if eth is NULL

esp_err_t esp_eth_phy_802_3_reset(phy_802_3_t *phy_802_3)

Reset PHY.

参数

phy_802_3 – IEEE 802.3 PHY object infostructure

返回

  • ESP_OK: Ethernet PHY reset successfuly

  • ESP_FAIL: reset Ethernet PHY failed because some error occured

esp_err_t esp_eth_phy_802_3_autonego_ctrl(phy_802_3_t *phy_802_3, eth_phy_autoneg_cmd_t cmd, bool *autonego_en_stat)

Control autonegotiation mode of Ethernet PHY.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • cmd – autonegotiation command enumeration

  • autonego_en_stat[out] autonegotiation enabled flag

返回

  • ESP_OK: Ethernet PHY autonegotiation configured successfuly

  • ESP_FAIL: Ethernet PHY autonegotiation configuration fail because some error occured

  • ESP_ERR_INVALID_ARG: invalid value of cmd

esp_err_t esp_eth_phy_802_3_pwrctl(phy_802_3_t *phy_802_3, bool enable)

Power control of Ethernet PHY.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • enable – set true to power ON Ethernet PHY; set false to power OFF Ethernet PHY

返回

  • ESP_OK: Ethernet PHY power down mode set successfuly

  • ESP_FAIL: Ethernet PHY power up or power down failed because some error occured

esp_err_t esp_eth_phy_802_3_set_addr(phy_802_3_t *phy_802_3, uint32_t addr)

Set Ethernet PHY address.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • addr – new PHY address

返回

  • ESP_OK: Ethernet PHY address set

esp_err_t esp_eth_phy_802_3_get_addr(phy_802_3_t *phy_802_3, uint32_t *addr)

Get Ethernet PHY address.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • addr[out] Ethernet PHY address

返回

  • ESP_OK: Ethernet PHY address read successfuly

  • ESP_ERR_INVALID_ARG: addr pointer is NULL

esp_err_t esp_eth_phy_802_3_advertise_pause_ability(phy_802_3_t *phy_802_3, uint32_t ability)

Advertise pause function ability.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • ability – enable or disable pause ability

返回

  • ESP_OK: pause ability set successfuly

  • ESP_FAIL: Advertise pause function ability failed because some error occured

esp_err_t esp_eth_phy_802_3_loopback(phy_802_3_t *phy_802_3, bool enable)

Set Ethernet PHY loopback mode.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • enable – set true to enable loopback; set false to disable loopback

返回

  • ESP_OK: Ethernet PHY loopback mode set successfuly

  • ESP_FAIL: Ethernet PHY loopback configuration failed because some error occured

esp_err_t esp_eth_phy_802_3_set_speed(phy_802_3_t *phy_802_3, eth_speed_t speed)

Set Ethernet PHY speed.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • speed – new speed of Ethernet PHY link

返回

  • ESP_OK: Ethernet PHY speed set successfuly

  • ESP_FAIL: Set Ethernet PHY speed failed because some error occured

esp_err_t esp_eth_phy_802_3_set_duplex(phy_802_3_t *phy_802_3, eth_duplex_t duplex)

Set Ethernet PHY duplex mode.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • duplex – new duplex mode for Ethernet PHY link

返回

  • ESP_OK: Ethernet PHY duplex mode set successfuly

  • ESP_ERR_INVALID_STATE: unable to set duplex mode to Half if loopback is enabled

  • ESP_FAIL: Set Ethernet PHY duplex mode failed because some error occured

Set Ethernet PHY link status.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • link – new link status

返回

  • ESP_OK: Ethernet PHY link set successfuly

esp_err_t esp_eth_phy_802_3_init(phy_802_3_t *phy_802_3)

Initialize Ethernet PHY.

参数

phy_802_3 – IEEE 802.3 PHY object infostructure

返回

  • ESP_OK: Ethernet PHY initialized successfuly

esp_err_t esp_eth_phy_802_3_deinit(phy_802_3_t *phy_802_3)

Power off Eternet PHY.

参数

phy_802_3 – IEEE 802.3 PHY object infostructure

返回

  • ESP_OK: Ethernet PHY powered off successfuly

esp_err_t esp_eth_phy_802_3_del(phy_802_3_t *phy_802_3)

Delete Ethernet PHY infostructure.

参数

phy_802_3 – IEEE 802.3 PHY object infostructure

返回

  • ESP_OK: Ethrnet PHY infostructure deleted

esp_err_t esp_eth_phy_802_3_reset_hw(phy_802_3_t *phy_802_3, uint32_t reset_assert_us)

Performs hardware reset with specific reset pin assertion time.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • reset_assert_us – Hardware reset pin assertion time

返回

  • ESP_OK: reset Ethernet PHY successfully

esp_err_t esp_eth_phy_802_3_detect_phy_addr(esp_eth_mediator_t *eth, int *detected_addr)

Detect PHY address.

参数
  • eth – Mediator of Ethernet driver

  • detected_addr[out] a valid address after detection

返回

  • ESP_OK: detect phy address successfully

  • ESP_ERR_INVALID_ARG: invalid parameter

  • ESP_ERR_NOT_FOUND: can’t detect any PHY device

  • ESP_FAIL: detect phy address failed because some error occurred

esp_err_t esp_eth_phy_802_3_basic_phy_init(phy_802_3_t *phy_802_3)

Performs basic PHY chip initialization.

备注

It should be called as the first function in PHY specific driver instance

参数

phy_802_3 – IEEE 802.3 PHY object infostructure

返回

  • ESP_OK: initialized Ethernet PHY successfully

  • ESP_FAIL: initialization of Ethernet PHY failed because some error occurred

  • ESP_ERR_INVALID_ARG: invalid argument

  • ESP_ERR_NOT_FOUND: PHY device not detected

  • ESP_ERR_TIMEOUT: MII Management read/write operation timeout

  • ESP_ERR_INVALID_STATE: PHY is in invalid state to perform requested operation

esp_err_t esp_eth_phy_802_3_basic_phy_deinit(phy_802_3_t *phy_802_3)

Performs basic PHY chip de-initialization.

备注

It should be called as the last function in PHY specific driver instance

参数

phy_802_3 – IEEE 802.3 PHY object infostructure

返回

  • ESP_OK: de-initialized Ethernet PHY successfully

  • ESP_FAIL: de-initialization of Ethernet PHY failed because some error occurred

  • ESP_ERR_TIMEOUT: MII Management read/write operation timeout

  • ESP_ERR_INVALID_STATE: PHY is in invalid state to perform requested operation

esp_err_t esp_eth_phy_802_3_read_oui(phy_802_3_t *phy_802_3, uint32_t *oui)

Reads raw content of OUI field.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • oui[out] OUI value

返回

  • ESP_OK: OUI field read successfully

  • ESP_FAIL: OUI field read failed because some error occurred

  • ESP_ERR_INVALID_ARG: invalid oui argument

  • ESP_ERR_TIMEOUT: MII Management read/write operation timeout

  • ESP_ERR_INVALID_STATE: PHY is in invalid state to perform requested operation

esp_err_t esp_eth_phy_802_3_read_manufac_info(phy_802_3_t *phy_802_3, uint8_t *model, uint8_t *rev)

Reads manufacturer’s model and revision number.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • model[out] Manufacturer’s model number (can be NULL when not required)

  • rev[out] Manufacturer’s revision number (can be NULL when not required)

返回

  • ESP_OK: Manufacturer’s info read successfully

  • ESP_FAIL: Manufacturer’s info read failed because some error occurred

  • ESP_ERR_TIMEOUT: MII Management read/write operation timeout

  • ESP_ERR_INVALID_STATE: PHY is in invalid state to perform requested operation

esp_err_t esp_eth_phy_802_3_get_mmd_addr(phy_802_3_t *phy_802_3, uint8_t devaddr, uint16_t *mmd_addr)

Reads MDIO device’s internal address register.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • devaddr – Address of MDIO device

  • mmd_addr[out] Current address stored in device’s register

返回

  • ESP_OK: Address register read successfuly

  • ESP_FAIL: Address register read failed because of some error occured

  • ESP_ERR_INVALID_ARG: Device address provided is out of range (hardware limits device address to 5 bits)

esp_err_t esp_eth_phy_802_3_set_mmd_addr(phy_802_3_t *phy_802_3, uint8_t devaddr, uint16_t mmd_addr)

Write to DIO device’s internal address register.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • devaddr – Address of MDIO device

  • mmd_addr[out] New value of MDIO device’s address register value

返回

  • ESP_OK: Address register written to successfuly

  • ESP_FAIL: Address register write failed because of some error occured

  • ESP_ERR_INVALID_ARG: Device address provided is out of range (hardware limits device address to 5 bits)

esp_err_t esp_eth_phy_802_3_read_mmd_data(phy_802_3_t *phy_802_3, uint8_t devaddr, esp_eth_phy_802_3_mmd_func_t function, uint32_t *data)

Read data of MDIO device’s memory at address register.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • devaddr – Address of MDIO device

  • function – MMD function

  • data[out] Data read from the device’s memory

返回

  • ESP_OK: Memory read successfuly

  • ESP_FAIL: Memory read failed because of some error occured

  • ESP_ERR_INVALID_ARG: Device address provided is out of range (hardware limits device address to 5 bits) or MMD access function is invalid

esp_err_t esp_eth_phy_802_3_write_mmd_data(phy_802_3_t *phy_802_3, uint8_t devaddr, esp_eth_phy_802_3_mmd_func_t function, uint32_t data)

Write data to MDIO device’s memory at address register.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • devaddr – Address of MDIO device

  • function – MMD function

  • data[out] Data to write to the device’s memory

返回

  • ESP_OK: Memory written successfuly

  • ESP_FAIL: Memory write failed because of some error occured

  • ESP_ERR_INVALID_ARG: Device address provided is out of range (hardware limits device address to 5 bits) or MMD access function is invalid

esp_err_t esp_eth_phy_802_3_read_mmd_register(phy_802_3_t *phy_802_3, uint8_t devaddr, uint16_t mmd_addr, uint32_t *data)

Set MMD address to mmd_addr with function MMD_FUNC_NOINCR and read contents to *data.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • devaddr – Address of MDIO device

  • mmd_addr – Address of MDIO device register

  • data[out] Data read from the device’s memory

返回

  • ESP_OK: Memory read successfuly

  • ESP_FAIL: Memory read failed because of some error occured

  • ESP_ERR_INVALID_ARG: Device address provided is out of range (hardware limits device address to 5 bits)

esp_err_t esp_eth_phy_802_3_write_mmd_register(phy_802_3_t *phy_802_3, uint8_t devaddr, uint16_t mmd_addr, uint32_t data)

Set MMD address to mmd_addr with function MMD_FUNC_NOINCR and write data.

参数
  • phy_802_3 – IEEE 802.3 PHY object infostructure

  • devaddr – Address of MDIO device

  • mmd_addr – Address of MDIO device register

  • data[out] Data to write to the device’s memory

返回

  • ESP_OK: Memory written to successfuly

  • ESP_FAIL: Memory write failed because of some error occured

  • ESP_ERR_INVALID_ARG: Device address provided is out of range (hardware limits device address to 5 bits)

inline phy_802_3_t *esp_eth_phy_into_phy_802_3(esp_eth_phy_t *phy)

Returns address to parent IEEE 802.3 PHY object infostructure.

参数

phy – Ethernet PHY instance

返回

phy_802_3_t*

  • address to parent IEEE 802.3 PHY object infostructure

esp_err_t esp_eth_phy_802_3_obj_config_init(phy_802_3_t *phy_802_3, const eth_phy_config_t *config)

Initializes configuration of parent IEEE 802.3 PHY object infostructure.

参数
  • phy_802_3 – Address to IEEE 802.3 PHY object infostructure

  • config – Configuration of the IEEE 802.3 PHY object

返回

  • ESP_OK: configuration initialized successfully

  • ESP_ERR_INVALID_ARG: invalid config argument

Structures

struct phy_802_3_t

IEEE 802.3 PHY object infostructure.

Public Members

esp_eth_phy_t parent

Parent Ethernet PHY instance

esp_eth_mediator_t *eth

Mediator of Ethernet driver

int addr

PHY address

uint32_t reset_timeout_ms

Reset timeout value (Unit: ms)

uint32_t autonego_timeout_ms

Auto-negotiation timeout value (Unit: ms)

Current Link status

int reset_gpio_num

Reset GPIO number, -1 means no hardware reset

Enumerations

enum esp_eth_phy_802_3_mmd_func_t

IEEE 802.3 MMD modes enumeration.

Values:

enumerator MMD_FUNC_ADDRESS
enumerator MMD_FUNC_DATA_NOINCR
enumerator MMD_FUNC_DATA_RWINCR
enumerator MMD_FUNC_DATA_WINCR

Header File

Functions

esp_eth_netif_glue_handle_t esp_eth_new_netif_glue(esp_eth_handle_t eth_hdl)

Create a netif glue for Ethernet driver.

备注

netif glue is used to attach io driver to TCP/IP netif

参数

eth_hdl – Ethernet driver handle

返回

glue object, which inherits esp_netif_driver_base_t

esp_err_t esp_eth_del_netif_glue(esp_eth_netif_glue_handle_t eth_netif_glue)

Delete netif glue of Ethernet driver.

参数

eth_netif_glue – netif glue

返回

-ESP_OK: delete netif glue successfully

Type Definitions

typedef struct esp_eth_netif_glue_t *esp_eth_netif_glue_handle_t

Handle of netif glue - an intermediate layer between netif and Ethernet driver.