USB 主机
本文档提供了 USB 主机库的相关信息,按以下章节展开:
概述
USB 主机库(以下简称主机库)是 USB 主机栈的最底层,提供面向公众开放的 API。应用程序使用 USB 主机功能时,通常无需与主机库直接交互,而是使用某个主机 Class 驱动提供的 API,这些主机 Class 驱动构建在主机库之上。
然而,由于以下的某些原因(但不仅限于此),有时你可能需要直接使用主机库:
需要实现自定义主机 Class 驱动程序
需要更低级别的抽象
特性和限制
主机库具有以下特性:
支持高速 (HS)、全速 (FS) 和低速 (LS) 设备。
支持四种传输类型,即控制传输、块传输、中断传输和同步传输。
支持高带宽等时性端点。
支持多个 Class 驱动程序同时运行,即主机的多个客户端同时运行。
单个设备可以由多个客户端同时使用,如复合设备。
主机库及其底层主机栈不会在内部自动创建操作系统任务,任务数量完全由主机库接口的使用方式决定。一般来说,任务数量为
(运行中的主机 Class 驱动程序数量 + 1)
。
目前,主机库及其底层主机栈存在以下限制:
仅支持单个设备,而主机库的 API 支持多设备。
仅支持异步传输。
仅支持使用发现的首个配置,尚不支持变更为其他配置。
尚不支持传输超时。
ESP32-P4 包含两个 USB-OTG 外设:USB 2.0 OTG 高速和 USB 2.0 OTG 全速。目前仅支持高速实例。
ESP32-P4 目前无法枚举低速设备。
架构
上图展示了使用 USB 主机功能时涉及的关键实体,包括:
主机库
主机库的 客户端
设备
主机库的 守护进程任务
主机库
主机库是 ESP-IDF USB 主机栈中面向公众开放的最底层的 API 层。任何其他 ESP-IDF 组件(如 Class 驱动程序或用户组件),如果需要与连接的 USB 设备通信,只能直接或间接使用主机库 API。
主机库 API 分为两类,即 库 API 和 客户端 API。
客户端 API 负责主机库的客户端与一或多个 USB 设备间的通信,该 API 只能由主机库的注册客户端调用。
库 API 负责主机库处理的通信中不特定于单个客户端的通信,如设备枚举。该 API 通常由主机库的守护进程任务调用。
客户端
主机库的客户端指使用主机库与 USB 设备通信的软件组件,如主机 Class 驱动程序或用户组件。每个客户端通常与任务间存在一对一关系,这表明,对特定客户端而言,其所有客户端 API 都应该在同一任务的上下文中调用。
通过将使用主机库的软件组件进行分类,划分为独立的客户端,主机库可以将所有客户端特定事件的处理委托给客户端对应的任务。换句话说,每个客户端任务负责管理与其对应的客户端之间的所有 USB 通信操作和事件处理,无需关心其他客户端的事件。
守护进程任务
尽管主机库将客户端事件的处理委托给客户端本身,但仍然需要处理主机库事件,即不特定于客户端的事件。主机库事件处理可能涉及以下内容:
处理 USB 设备的连接、枚举和断连
将控制传输从/向客户端进行重定向
将事件转发给客户端
因此,除客户端任务外,主机库也需要一个任务来处理所有的库事件,这个任务通常是主机库守护进程任务。
设备
主机库隔离了客户端与设备处理的细节,包括连接、内存分配和枚举等,客户端只需提供已连接且已枚举的设备列表供选择。默认情况下,在枚举过程中,每个设备都会自动配置为使用找到的第一个配置,即通过获取配置描述符请求返回的第一个配置描述符。对于大多数标准设备,通常将第一个配置的 bConfigurationValue
设置为 1
。启用选项 CONFIG_USB_HOST_ENABLE_ENUM_FILTER_CALLBACK 后,可以选择不同的 bConfigurationValue
。获取更多详细信息,请参阅 Multiple configuration Support_。
只要不与相同接口通信,两个及以上的客户端可以同时与同一设备通信。然而,多个客户端同时与相同设备的默认端点(即 EP0)通信,将导致它们的控制传输序列化。
要与设备通信,客户端必须满足以下条件:
使用设备地址打开设备,告知主机库,客户端正在使用该设备。
获取将用于通信的接口,防止其他客户端获取相同的接口。
通过已经获取了使用权的设备接口的端点通信通道发送数据传输。客户端的任务负责处理其与 USB 设备通信相关的操作和事件。
用法
主机库及底层主机栈不会创建任何任务,客户端任务和守护进程任务等均需由 Class 驱动程序或用户自行创建。然而,主机库提供了两个事件处理函数,可以处理所有必要的主机库操作,这些函数应从客户端任务和守护进程任务中重复调用。因此,客户端任务和守护进程任务的使用将主要集中于调用这些事件处理函数。
主机库与守护进程任务
基本用法
主机库 API 提供了 usb_host_lib_handle_events()
,可以处理库事件。该函数需要反复调用,通常是从守护进程任务中调用。函数 usb_host_lib_handle_events()
有以下特点:
该函数会持续阻塞,直至需要处理库事件。
每次调用该函数都会返回事件标志,有助于了解卸载主机库的时机。
最基础的守护进程任务通常类似以下代码片段:
#include "usb/usb_host.h"
void daemon_task(void *arg)
{
...
bool exit = false;
while (!exit) {
uint32_t event_flags;
usb_host_lib_handle_events(portMAX_DELAY, &event_flags);
if (event_flags & USB_HOST_LIB_EVENT_FLAGS_NO_CLIENTS) {
...
}
if (event_flags & USB_HOST_LIB_EVENT_FLAGS_ALL_FREE) {
...
}
...
}
...
}
备注
了解守护进程任务的完整示例,请前往 peripherals/usb/host/usb_host_lib。
生命周期
上图展示了 USB 主机库的典型生命周期,其中涉及多个客户端和设备。具体而言,示例涉及以下内容:
两个已注册的客户端(客户端 1 和客户端 2)。
两个已连接的设备(设备 1 和设备 2),其中客户端 1 与设备 1 通信,客户端 2 与设备 2 通信。
参考上图可知,典型 USB 主机库生命周期包括以下关键阶段:
- 调用
usb_host_install()
,安装主机库。 调用任意主机库 API 前,请确保已完成主机库安装。
调用
usb_host_install()
的位置(如从守护进程任务或其他任务中调用)取决于守护系统任务、客户端任务和系统其余部分间的同步逻辑。
- 调用
- 安装完主机库后,调用
usb_host_client_register()
注册客户端。 该注册函数通常从客户端任务调用,而客户端任务需等待来自守护进程任务的信号。
调用过
usb_host_install()
后,如有需要,也可以在其他地方调用该注册函数。
- 安装完主机库后,调用
- 设备 1 连接,并进行枚举。
每个已注册的客户端(本案例中为客户端 1 和客户端 2)都会通过
USB_HOST_CLIENT_EVENT_NEW_DEV
事件得到新设备的通知。客户端 1 开启设备 1,并与之通信。
- 设备 2 连接,并进行枚举。
客户端 1 和 2 通过
USB_HOST_CLIENT_EVENT_NEW_DEV
事件得到新设备的通知。客户端 2 开启设备 2,并与之通信。
- 设备 1 突然断开连接。
客户端 1 通过
USB_HOST_CLIENT_EVENT_DEV_GONE
得到通知,并开始清理,关闭和释放客户端 1 与设备 1 之间的关联资源。客户端 2 不会收到通知,因为它并未开启设备 1。
- 客户端 1 完成清理,调用
usb_host_client_deregister()
注销客户端。 该注销函数通常在任务退出前,从客户端任务中调用。
如有需要,只要客户端 1 已完成清理,也可以在其他地方调用该注销函数。
- 客户端 1 完成清理,调用
- 客户端 2 完成与设备 2 的通信,随后关闭设备 2,并自行注销。
由于客户端 2 是最后一个注销的客户端,通过
USB_HOST_LIB_EVENT_FLAGS_NO_CLIENTS
事件标志,守护进程任务可以得知,所有客户端已注销。设备 2 未释放,仍会进行分配,因为虽然没有任何客户端打开设备 2,但它仍处于连接状态。
- 所有客户端注销后,守护进程任务开始清理。
守护进程任务需要先调用
usb_host_device_free_all()
,释放设备 2。如果
usb_host_device_free_all()
能够成功释放所有设备,函数将返回 ESP_OK,表明已释放所有设备。如果
usb_host_device_free_all()
无法成功释放所有设备,例如因为设备仍由某个客户端开启,函数将返回 ESP_ERR_NOT_FINISHED。守护进程任务必须等待
usb_host_lib_handle_events()
返回事件标志USB_HOST_LIB_EVENT_FLAGS_ALL_FREE
,方知何时所有设备均已释放。
一旦守护进程任务确认所有客户端均已注销,且所有设备均已释放,便可调用
usb_host_uninstall()
,卸载主机库。
客户端与 Class 驱动程序
基本用法
主机库 API 提供函数 usb_host_client_handle_events()
,可以处理特定客户端事件。该函数需要反复调用,通常是从客户端任务中调用。函数 usb_host_client_handle_events()
有以下特点:
该函数可以持续阻塞,直至需要处理客户端事件。
该函数的主要目的是发生客户端事件时,调用多个事件处理回调函数。
以下回调函数均从 usb_host_client_handle_events()
中调用,因此客户端任务能够获取事件通知。
类型为
usb_host_client_event_cb_t
的客户端事件回调函数会将客户端事件消息传递给客户端,提示添加、移除设备等事件。类型为
usb_transfer_cb_t
的 USB 传输完成回调函数表明,先前由客户端提交的特定 USB 传输已完成。
备注
考虑到上述回调函数从 usb_host_client_handle_events()
中调用,应避免在回调函数内部阻塞,否则将导致 usb_host_client_handle_events()
阻塞,阻止其他待处理的客户端事件得到处理。
以下代码片段展示了一个基础的主机 Class 驱动程序及其客户端任务,代码片段中包括:
一个简单的客户端任务函数
client_task
,它会在循环中调用usb_host_client_handle_events()
。使用客户端事件回调函数和传输完成回调函数。
一个用于 Class 驱动程序的简单状态机。该 Class 驱动程序仅支持打开设备,发送 OUT 传输到 EP1,然后关闭设备。
#include <string.h>
#include "usb/usb_host.h"
#define CLASS_DRIVER_ACTION_OPEN_DEV 0x01
#define CLASS_DRIVER_ACTION_TRANSFER 0x02
#define CLASS_DRIVER_ACTION_CLOSE_DEV 0x03
struct class_driver_control {
uint32_t actions;
uint8_t dev_addr;
usb_host_client_handle_t client_hdl;
usb_device_handle_t dev_hdl;
};
static void client_event_cb(const usb_host_client_event_msg_t *event_msg, void *arg)
{
//该函数从 usb_host_client_handle_events() 中调用,请勿在此阻塞,并尽量保持简洁
struct class_driver_control *class_driver_obj = (struct class_driver_control *)arg;
switch (event_msg->event) {
case USB_HOST_CLIENT_EVENT_NEW_DEV:
class_driver_obj->actions |= CLASS_DRIVER_ACTION_OPEN_DEV;
class_driver_obj->dev_addr = event_msg->new_dev.address; //存储新设备的地址
break;
case USB_HOST_CLIENT_EVENT_DEV_GONE:
class_driver_obj->actions |= CLASS_DRIVER_ACTION_CLOSE_DEV;
break;
default:
break;
}
}
static void transfer_cb(usb_transfer_t *transfer)
{
//该函数从 usb_host_client_handle_events() 中调用,请勿在此阻塞,并尽量保持简洁
struct class_driver_control *class_driver_obj = (struct class_driver_control *)transfer->context;
printf("Transfer status %d, actual number of bytes transferred %d\n", transfer->status, transfer->actual_num_bytes);
class_driver_obj->actions |= CLASS_DRIVER_ACTION_CLOSE_DEV;
}
void client_task(void *arg)
{
... //等待主机库安装
//初始化 Class 驱动程序对象
struct class_driver_control class_driver_obj = {0};
//注册客户端
usb_host_client_config_t client_config = {
.is_synchronous = false,
.max_num_event_msg = 5,
.async = {
.client_event_callback = client_event_cb,
.callback_arg = &class_driver_obj,
}
};
usb_host_client_register(&client_config, &class_driver_obj.client_hdl);
//分配一个 USB 传输
usb_transfer_t *transfer;
usb_host_transfer_alloc(1024, 0, &transfer);
//事件处理循环
bool exit = false;
while (!exit) {
//调用客户端事件处理函数
usb_host_client_handle_events(class_driver_obj.client_hdl, portMAX_DELAY);
//执行待处理的 Class 驱动程序操作
if (class_driver_obj.actions & CLASS_DRIVER_ACTION_OPEN_DEV) {
//开启设备,声明接口 1
usb_host_device_open(class_driver_obj.client_hdl, class_driver_obj.dev_addr, &class_driver_obj.dev_hdl);
usb_host_interface_claim(class_driver_obj.client_hdl, class_driver_obj.dev_hdl, 1, 0);
}
if (class_driver_obj.actions & CLASS_DRIVER_ACTION_TRANSFER) {
//发送一个 OUT 传输到 EP1
memset(transfer->data_buffer, 0xAA, 1024);
transfer->num_bytes = 1024;
transfer->device_handle = class_driver_obj.dev_hdl;
transfer->bEndpointAddress = 0x01;
transfer->callback = transfer_cb;
transfer->context = (void *)&class_driver_obj;
usb_host_transfer_submit(transfer);
}
if (class_driver_obj.actions & CLASS_DRIVER_ACTION_CLOSE_DEV) {
//释放接口,关闭设备
usb_host_interface_release(class_driver_obj.client_hdl, class_driver_obj.dev_hdl, 1);
usb_host_device_close(class_driver_obj.client_hdl, class_driver_obj.dev_hdl);
exit = true;
}
... //处理其他 Class 驱动程序要求的行为
}
//清理 Class 驱动程序
usb_host_transfer_free(transfer);
usb_host_client_deregister(class_driver_obj.client_hdl);
... //删除客户端任务。如有需要,向守护进程任务发送信号。
}
备注
在实际应用中,主机 Class 驱动程序还能支持更多功能,因此也存在更复杂的状态机。主机 Class 驱动程序可能需要:
能够开启多个设备
解析已开启设备的描述符,确定设备是否是目标 Class
按特定顺序,与接口的多个端点通信
声明设备的多个接口
处理各种错误情况
生命周期
客户端任务与 Class 驱动程序的典型生命周期包括以下关键阶段:
等待与主机库有关的信号完成安装。
通过
usb_host_client_register()
注册客户端,并分配其他的 Class 驱动程序资源,如使用usb_host_transfer_alloc()
分配传输。对于 Class 驱动程序需要与之通信的各个新设备:
调用
usb_host_device_addr_list_fill()
,检查设备是否已连接。如果设备尚未连接,则等待客户端事件回调函数的
USB_HOST_CLIENT_EVENT_NEW_DEV
事件。调用
usb_host_device_open()
开启设备。分别调用
usb_host_get_device_descriptor()
和usb_host_get_active_config_descriptor()
,解析设备和配置描述符。调用
usb_host_interface_claim()
,声明设备的必要接口。
调用
usb_host_transfer_submit()
或usb_host_transfer_submit_control()
,向设备提交传输。一旦
USB_HOST_CLIENT_EVENT_DEV_GONE
事件表示,Class 驱动程序不再需要已打开的设备,或者设备断开连接:在这些端点上调用
usb_host_endpoint_halt()
和usb_host_endpoint_flush()
,停止先前提交的传输。调用
usb_host_interface_release()
,释放先前声明的所有接口。调用
usb_host_device_close()
,关闭设备。
调用
usb_host_client_deregister()
注销客户端,并释放其他 Class 驱动程序资源。删除客户端任务。如有需要,向守护进程任务发送信号。
示例
主机库示例
peripherals/usb/host/usb_host_lib 展示了 USB 主机库 API 的基本用法,用于创建伪 Class 驱动程序。
Class 驱动程序示例
USB 主机栈提供了大量示例,展示了如何通过使用主机库 API 创建主机 Class 驱动程序。
CDC-ACM
通信设备 Class(抽象控制模型)的主机 Class 驱动程序通过 ESP-IDF 组件注册器 作为受管理的组件分发。
示例 peripherals/usb/host/cdc/cdc_acm_host 使用 CDC-ACM 主机驱动程序组件,与 CDC-ACM 设备通信。
示例 peripherals/usb/host/cdc/cdc_acm_vcp 展示了如何扩展 CDC-ACM 主机驱动程序,与虚拟串口设备交互。
示例 esp_modem 中也使用了 CDC-ACM 驱动程序,该程序在这些示例中与蜂窝模块通信。
MSC
大容量存储 Class(仅支持批量传输)的主机 Class 驱动程序已部署到 ESP-IDF 组件注册器。
示例 peripherals/usb/host/msc 展示了如何使用 MSC 主机驱动程序读写 USB flash 驱动。
HID
HID(人机接口设备)的主机 class 驱动作为托管组件通过 ESP-IDF 组件注册器 分发。
示例 peripherals/usb/host/hid 展示了从具有多个接口的 USB HID 设备接收报告的可能性。
UVC
USB 视频设备 Class 的主机 Class 驱动程序作为托管组件通过 ESP-IDF 组件注册器 分发。
示例 peripherals/usb/host/uvc 展示了如何使用 UVC 主机驱动程序接收来自 USB 摄像头的视频流,并可选择将该流通过 Wi-Fi 转发。
主机栈配置
非兼容设备支持
为了支持某些非兼容或具有特定行为的 USB 设备,可以对 USB 主机栈进行配置。
USB 设备可能是热插拔的,因此必须配置电源开关和设备连接之间的延迟,以及设备内部电源稳定后的延迟。
枚举配置
在枚举已连接 USB 设备的过程中,需要给一些事件配置合适的间隔时间以确保设备正常运行。
上图展示了与连接设备时开启端口电源和热插拔设备相关的所有间隔时间。
端口复位或恢复运行后,USB 系统软件应提供 10 毫秒的恢复时间,此后连接到端口的设备才会响应数据传输。
恢复时间结束后,如果设备收到
SetAddress()
请求,设备必须能够完成对该请求的处理,并能在 50 毫秒内成功完成请求的状态 (Status) 阶段。状态阶段结束后,设备允许有 2 毫秒的
SetAddress()
恢复时间。
备注
有关连接事件时序的更多信息,请参阅 通用串行总线 2.0 规范 > 第 7.1.7.3 章 连接和断开信令。
可通过 Menuconfig 选项设置 USB 主机栈的可配置参数。
CONFIG_USB_HOST_DEBOUNCE_DELAY_MS 用于配置防抖延迟。
CONFIG_USB_HOST_RESET_HOLD_MS 用于配置重置保持时间。
CONFIG_USB_HOST_RESET_RECOVERY_MS 用于配置重置恢复时间。
CONFIG_USB_HOST_SET_ADDR_RECOVERY_MS 用于配置
SetAddress()
恢复时间。
多项配置支持
对于具有多项配置的 USB 设备,可以在设备枚举过程中指定所需的配置编号。
枚举过滤器
枚举过滤器是类型为 usb_host_enum_filter_cb_t
的回调函数。从新连接的 USB 设备上读取设备描述符后,USB 主机栈会在枚举过程开始时调用枚举过滤器,从而为用户提供读取的设备描述符。借助此回调,用户得以:
选择 USB 设备的配置。
过滤应该进行枚举的 USB 设备。
在 menuconfig 中启用 CONFIG_USB_HOST_ENABLE_ENUM_FILTER_CALLBACK 选项即可启用枚举过滤器。可以通过设置 usb_host_config_t::enum_filter_cb
来指定回调函数,该函数会在调用 usb_host_install()
时传递至主机库。
API 参考
USB 主机库的 API 包含以下头文件,但应用程序调用该 API 时只需 #include "usb/usb_host.h"
,该头文件包含了所有 USB 主机库的头文件。
usb/include/usb/usb_host.h 包含 USB 主机库的函数和类型。
usb/include/usb/usb_helpers.h 包含与 USB 协议相关的各种辅助函数,如描述符解析等。
usb/include/usb/usb_types_stack.h 包含在 USB 主机栈的多个层次中使用的类型。
usb/include/usb/usb_types_ch9.h 包含了与 USB 2.0 规范中第 9 章相关的类型和宏,即描述符和标准请求。
Header File
This header file can be included with:
#include "usb/usb_host.h"
This header file is a part of the API provided by the
usb
component. To declare that your component depends onusb
, add the following to your CMakeLists.txt:REQUIRES usb
or
PRIV_REQUIRES usb
Functions
-
esp_err_t usb_host_install(const usb_host_config_t *config)
Install the USB Host Library.
This function should be called only once to install the USB Host Library
This function should be called before any other USB Host Library functions are called
备注
If skip_phy_setup is set in the install configuration, the user is responsible for ensuring that the underlying Host Controller is enabled and the USB PHY (internal or external) is already setup before this function is called.
- 参数
config -- [in] USB Host Library configuration
- 返回
ESP_OK: USB Host installed successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_INVALID_STATE: USB Host Library is not in correct state to be installed (eg. the library itself of one of it's drivers is already installed)
ESP_ERR_NO_MEM: Insufficient memory
-
esp_err_t usb_host_uninstall(void)
Uninstall the USB Host Library.
This function should be called to uninstall the USB Host Library, thereby freeing its resources
All clients must have been deregistered before calling this function
All devices must have been freed by calling usb_host_device_free_all() and receiving the USB_HOST_LIB_EVENT_FLAGS_ALL_FREE event flag
备注
If skip_phy_setup was set when the Host Library was installed, the user is responsible for disabling the underlying Host Controller and USB PHY (internal or external).
- 返回
ESP_OK: USB Host uninstalled successfully
ESP_ERR_INVALID_STATE: USB Host Library is not installed, or has unfinished actions
-
esp_err_t usb_host_lib_handle_events(TickType_t timeout_ticks, uint32_t *event_flags_ret)
Handle USB Host Library events.
This function handles all of the USB Host Library's processing and should be called repeatedly in a loop
Check event_flags_ret to see if an flags are set indicating particular USB Host Library events
This function should never be called by multiple threads simultaneously
备注
This function can block
- 参数
timeout_ticks -- [in] Timeout in ticks to wait for an event to occur
event_flags_ret -- [out] Event flags that indicate what USB Host Library event occurred.
- 返回
ESP_OK: No events to be handled
ESP_ERR_INVALID_STATE: USB Host Library is not installed
ESP_ERR_TIMEOUT: Semaphore waiting for events has timed out
-
esp_err_t usb_host_lib_unblock(void)
Unblock the USB Host Library handler.
This function simply unblocks the USB Host Library event handling function (usb_host_lib_handle_events())
- 返回
ESP_OK: USB Host library unblocked successfully
ESP_ERR_INVALID_STATE: USB Host Library is not installed
-
esp_err_t usb_host_lib_info(usb_host_lib_info_t *info_ret)
Get current information about the USB Host Library.
- 参数
info_ret -- [out] USB Host Library Information
- 返回
ESP_OK: USB Host Library info obtained successfully
ESP_ERR_INVALID_STATE: USB Host Library is not installed
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_lib_set_root_port_power(bool enable)
Power the root port ON or OFF.
Powering ON the root port will allow device connections to occur
Powering OFF the root port will disconnect all devices downstream off the root port and prevent any further device connections.
备注
If 'usb_host_config_t.root_port_unpowered' was set on USB Host Library installation, users must call this function to power ON the root port before any device connections can occur.
- 参数
enable -- [in] True to power the root port ON, false to power OFF
- 返回
ESP_OK: Root port power enabled/disabled
ESP_ERR_INVALID_STATE: Root port already powered or HUB driver not installed
-
esp_err_t usb_host_client_register(const usb_host_client_config_t *client_config, usb_host_client_handle_t *client_hdl_ret)
Register a client of the USB Host Library.
This function registers a client of the USB Host Library
Once a client is registered, its processing function usb_host_client_handle_events() should be called repeatedly
- 参数
client_config -- [in] Client configuration
client_hdl_ret -- [out] Client handle
- 返回
ESP_OK: USB Host Library client registered successfully
ESP_ERR_INVALID_STATE: USB Host Library is not installed
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_NO_MEM: Insufficient memory
-
esp_err_t usb_host_client_deregister(usb_host_client_handle_t client_hdl)
Deregister a USB Host Library client.
This function deregisters a client of the USB Host Library
The client must have closed all previously opened devices before attempting to deregister
- 参数
client_hdl -- [in] Client handle
- 返回
ESP_OK: USB Host Library client deregistered successfully
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_client_handle_events(usb_host_client_handle_t client_hdl, TickType_t timeout_ticks)
USB Host Library client processing function.
This function handles all of a client's processing and should be called repeatedly in a loop
For a particular client, this function should never be called by multiple threads simultaneously
备注
This function can block
- 参数
client_hdl -- [in] Client handle
timeout_ticks -- [in] Timeout in ticks to wait for an event to occur
- 返回
ESP_OK: No event to be handled
ESP_ERR_INVALID_STATE: USB Host Library is not installed
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_TIMEOUT: Semaphore waiting for events has timed out
-
esp_err_t usb_host_client_unblock(usb_host_client_handle_t client_hdl)
Unblock a client.
This function simply unblocks a client if it is blocked on the usb_host_client_handle_events() function.
This function is useful when need to unblock a client in order to deregister it.
- 参数
client_hdl -- [in] Client handle
- 返回
ESP_OK: Client unblocked successfully
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_device_open(usb_host_client_handle_t client_hdl, uint8_t dev_addr, usb_device_handle_t *dev_hdl_ret)
Open a device.
This function allows a client to open a device
A client must open a device first before attempting to use it (e.g., sending transfers, device requests etc.)
- 参数
client_hdl -- [in] Client handle
dev_addr -- [in] Device's address
dev_hdl_ret -- [out] Device's handle
- 返回
ESP_OK: Device opened successfully
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_device_close(usb_host_client_handle_t client_hdl, usb_device_handle_t dev_hdl)
Close a device.
This function allows a client to close a device
A client must close a device after it has finished using the device (claimed interfaces must also be released)
A client must close all devices it has opened before de-registering
备注
This function can block
- 参数
client_hdl -- [in] Client handle
dev_hdl -- [in] Device handle
- 返回
ESP_OK: Device closed successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_NOT_FOUND: Device address not found among opened devices
ESP_ERR_INVALID_STATE: The client never opened the device, or the client has not released all the interfaces from the device
-
esp_err_t usb_host_device_free_all(void)
Indicate that all devices can be freed when possible.
This function marks all devices as waiting to be freed
If a device is not opened by any clients, it will be freed immediately
If a device is opened by at least one client, the device will be free when the last client closes that device.
Wait for the USB_HOST_LIB_EVENT_FLAGS_ALL_FREE flag to be set by usb_host_lib_handle_events() in order to know when all devices have been freed
This function is useful when cleaning up devices before uninstalling the USB Host Library
- 返回
ESP_OK: All devices already freed (i.e., there were no devices)
ESP_ERR_INVALID_STATE: Client must be deregistered
ESP_ERR_NOT_FINISHED: There are one or more devices that still need to be freed, wait for USB_HOST_LIB_EVENT_FLAGS_ALL_FREE event
-
esp_err_t usb_host_device_addr_list_fill(int list_len, uint8_t *dev_addr_list, int *num_dev_ret)
Fill a list of device address.
This function fills an empty list with the address of connected devices
The Device addresses can then used in usb_host_device_open()
If there are more devices than the list_len, this function will only fill up to list_len number of devices.
- 参数
list_len -- [in] Length of the empty list
dev_addr_list -- [inout] Empty list to be filled
num_dev_ret -- [out] Number of devices
- 返回
ESP_OK: Device list filled successfully
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_device_info(usb_device_handle_t dev_hdl, usb_device_info_t *dev_info)
Get device's information.
This function gets some basic information of a device
The device must be opened first before attempting to get its information
备注
This function can block
- 参数
dev_hdl -- [in] Device handle
dev_info -- [out] Device information
- 返回
ESP_OK: Device information obtained successfully
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_get_device_descriptor(usb_device_handle_t dev_hdl, const usb_device_desc_t **device_desc)
Get device's device descriptor.
A client must call usb_host_device_open() first
No control transfer is sent. The device's descriptor is cached on enumeration
This function simple returns a pointer to the cached descriptor
备注
No control transfer is sent. The device's descriptor is cached on enumeration
- 参数
dev_hdl -- [in] Device handle
device_desc -- [out] Device descriptor
- 返回
ESP_OK: Device descriptor obtained successfully
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_get_active_config_descriptor(usb_device_handle_t dev_hdl, const usb_config_desc_t **config_desc)
Get device's active configuration descriptor.
A client must call usb_host_device_open() first
No control transfer is sent. The device's active configuration descriptor is cached on enumeration
This function simple returns a pointer to the cached descriptor
备注
This function can block
备注
No control transfer is sent. A device's active configuration descriptor is cached on enumeration
- 参数
dev_hdl -- [in] Device handle
config_desc -- [out] Configuration descriptor
- 返回
ESP_OK: Active configuration descriptor obtained successfully
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_get_config_desc(usb_host_client_handle_t client_hdl, usb_device_handle_t dev_hdl, uint8_t bConfigurationValue, const usb_config_desc_t **config_desc_ret)
Get get device's configuration descriptor.
The USB Host library only caches a device's active configuration descriptor.
This function reads any configuration descriptor of a particular device (specified by bConfigurationValue).
This function will read the specified configuration descriptor via control transfers, and allocate memory to store that descriptor.
Users can call usb_host_free_config_desc() to free the descriptor's memory afterwards.
备注
This function can block
备注
A client must call usb_host_device_open() on the device first
备注
bConfigurationValue starts from index 1
- 参数
client_hdl -- [in] Client handle - usb_host_client_handle_events() should be called repeatedly in a separate task to handle client events
dev_hdl -- [in] Device handle
bConfigurationValue -- [in] Index of device's configuration descriptor to be read
config_desc_ret -- [out] Returned configuration descriptor
- 返回
ESP_OK: Configuration descriptor obtained successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_NOT_SUPPORTED: Invalid bConfigurationValue value (the device does not have this configuration value)
ESP_ERR_NO_MEM: Insufficient memory
-
esp_err_t usb_host_free_config_desc(const usb_config_desc_t *config_desc)
Free a configuration descriptor.
This function frees a configuration descriptor that was returned by usb_host_get_config_desc()
- 参数
config_desc -- [out] Configuration descriptor
- 返回
ESP_OK: Configuration descriptor freed successfully
ESP_ERR_INVALID_ARG: Invalid argument
-
esp_err_t usb_host_interface_claim(usb_host_client_handle_t client_hdl, usb_device_handle_t dev_hdl, uint8_t bInterfaceNumber, uint8_t bAlternateSetting)
Function for a client to claim a device's interface.
A client must claim a device's interface before attempting to communicate with any of its endpoints
Once an interface is claimed by a client, it cannot be claimed by any other client.
备注
This function can block
- 参数
client_hdl -- [in] Client handle
dev_hdl -- [in] Device handle
bInterfaceNumber -- [in] Interface number
bAlternateSetting -- [in] Interface alternate setting number
- 返回
ESP_OK: Interface claimed successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_INVALID_STATE: USB Host is not a correct state to claim an interface
ESP_ERR_NOT_FOUND: Interface or EP not found
ESP_ERR_NO_MEM: Insufficient memory
-
esp_err_t usb_host_interface_release(usb_host_client_handle_t client_hdl, usb_device_handle_t dev_hdl, uint8_t bInterfaceNumber)
Function for a client to release a previously claimed interface.
A client should release a device's interface after it no longer needs to communicate with the interface
A client must release all of its interfaces of a device it has claimed before being able to close the device
备注
This function can block
- 参数
client_hdl -- [in] Client handle
dev_hdl -- [in] Device handle
bInterfaceNumber -- [in] Interface number
- 返回
ESP_OK: Interface released successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_INVALID_STATE: Client never opened the USB Device, or interface currently can not be freed
ESP_ERR_NOT_FOUND: Interface number not found in the list of interfaces
-
esp_err_t usb_host_endpoint_halt(usb_device_handle_t dev_hdl, uint8_t bEndpointAddress)
Halt a particular endpoint.
The device must have been opened by a client
The endpoint must be part of an interface claimed by a client
Once halted, the endpoint must be cleared using usb_host_endpoint_clear() before it can communicate again
备注
This function can block
- 参数
dev_hdl -- [in] Device handle
bEndpointAddress -- [in] Endpoint address
- 返回
ESP_OK: Endpoint halted successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_NOT_FOUND: Endpoint address not found
ESP_ERR_INVALID_STATE: Endpoint pipe is not in the correct state/condition to execute a command
-
esp_err_t usb_host_endpoint_flush(usb_device_handle_t dev_hdl, uint8_t bEndpointAddress)
Flush a particular endpoint.
The device must have been opened by a client
The endpoint must be part of an interface claimed by a client
The endpoint must have been halted (either through a transfer error, or usb_host_endpoint_halt())
Flushing an endpoint will caused an queued up transfers to be canceled
备注
This function can block
- 参数
dev_hdl -- [in] Device handle
bEndpointAddress -- [in] Endpoint address
- 返回
ESP_OK: Endpoint flushed successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_NOT_FOUND: Endpoint address not found
ESP_ERR_INVALID_STATE: Endpoint pipe is not in the correct state/condition to execute a command
-
esp_err_t usb_host_endpoint_clear(usb_device_handle_t dev_hdl, uint8_t bEndpointAddress)
Clear a halt on a particular endpoint.
The device must have been opened by a client
The endpoint must be part of an interface claimed by a client
The endpoint must have been halted (either through a transfer error, or usb_host_endpoint_halt())
If the endpoint has any queued up transfers, clearing a halt will resume their execution
备注
This function can block
- 参数
dev_hdl -- [in] Device handle
bEndpointAddress -- [in] Endpoint address
- 返回
ESP_OK: Endpoint cleared successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_NOT_FOUND: Endpoint address not found
ESP_ERR_INVALID_STATE: Endpoint pipe is not in the correct state/condition to execute a command
-
esp_err_t usb_host_transfer_alloc(size_t data_buffer_size, int num_isoc_packets, usb_transfer_t **transfer)
Allocate a transfer object.
This function allocates a transfer object
Each transfer object has a fixed sized buffer specified on allocation
A transfer object can be re-used indefinitely
A transfer can be submitted using usb_host_transfer_submit() or usb_host_transfer_submit_control()
- 参数
data_buffer_size -- [in] Size of the transfer's data buffer
num_isoc_packets -- [in] Number of isochronous packets in transfer (set to 0 for non-isochronous transfers)
transfer -- [out] Transfer object
- 返回
ESP_OK: Transfer object allocated successfully
ESP_ERR_NO_MEM: Insufficient memory
-
esp_err_t usb_host_transfer_free(usb_transfer_t *transfer)
Free a transfer object.
Free a transfer object previously allocated using usb_host_transfer_alloc()
The transfer must not be in-flight when attempting to free it
If a NULL pointer is passed, this function will simply return ESP_OK
- 参数
transfer -- [in] Transfer object
- 返回
ESP_OK: Transfer object freed successfully
-
esp_err_t usb_host_transfer_submit(usb_transfer_t *transfer)
Submit a non-control transfer.
Submit a transfer to a particular endpoint. The device and endpoint number is specified inside the transfer
The transfer must be properly initialized before submitting
On completion, the transfer's callback will be called from the client's usb_host_client_handle_events() function.
- 参数
transfer -- [in] Initialized transfer object
- 返回
ESP_OK: Transfer submitted successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_NOT_FINISHED: Transfer already in-flight
ESP_ERR_NOT_FOUND: Endpoint address not found
ESP_ERR_INVALID_STATE: Endpoint pipe is not in a correct state to submit transfer
-
esp_err_t usb_host_transfer_submit_control(usb_host_client_handle_t client_hdl, usb_transfer_t *transfer)
Submit a control transfer.
Submit a control transfer to a particular device. The client must have opened the device first
The transfer must be properly initialized before submitting. The first 8 bytes of the transfer's data buffer should contain the control transfer setup packet
On completion, the transfer's callback will be called from the client's usb_host_client_handle_events() function.
- 参数
client_hdl -- [in] Client handle
transfer -- [in] Initialized transfer object
- 返回
ESP_OK: Control transfer submitted successfully
ESP_ERR_INVALID_ARG: Invalid argument
ESP_ERR_NOT_FINISHED: Transfer already in-flight
ESP_ERR_NOT_FOUND: Endpoint address not found
ESP_ERR_INVALID_STATE: Endpoint pipe is not in a correct state to submit transfer
Structures
-
struct usb_host_client_event_msg_t
Client event message.
Client event messages are sent to each client of the USB Host Library in order to notify them of various USB Host Library events such as:
Addition of new devices
Removal of existing devices
备注
The event message structure has a union with members corresponding to each particular event. Based on the event type, only the relevant member field should be accessed.
Public Members
-
usb_host_client_event_t event
Type of event
-
uint8_t address
New device's address
-
struct usb_host_client_event_msg_t::[anonymous]::[anonymous] new_dev
New device info
-
usb_device_handle_t dev_hdl
The handle of the device that was gone
-
struct usb_host_client_event_msg_t::[anonymous]::[anonymous] dev_gone
Gone device info
-
struct usb_host_lib_info_t
Current information about the USB Host Library obtained via usb_host_lib_info()
-
struct usb_host_config_t
USB Host Library configuration.
Configuration structure of the USB Host Library. Provided in the usb_host_install() function
Public Members
-
bool skip_phy_setup
If set, the USB Host Library will not configure the USB PHY thus allowing the user to manually configure the USB PHY before calling usb_host_install(). Users should set this if they want to use an external USB PHY. Otherwise, the USB Host Library will automatically configure the internal USB PHY
-
bool root_port_unpowered
If set, the USB Host Library will not power on the root port on installation. This allows users to power on the root port manually by calling usb_host_lib_set_root_port_power().
-
int intr_flags
Interrupt flags for the underlying ISR used by the USB Host stack
-
usb_host_enum_filter_cb_t enum_filter_cb
Enumeration filter callback. Enable CONFIG_USB_HOST_ENABLE_ENUM_FILTER_CALLBACK to use this feature. Set to NULL otherwise.
-
bool skip_phy_setup
-
struct usb_host_client_config_t
USB Host Library Client configuration.
Configuration structure for a USB Host Library client. Provided in usb_host_client_register()
Public Members
-
bool is_synchronous
Whether the client is asynchronous or synchronous or not. Set to false for now.
-
int max_num_event_msg
Maximum number of event messages that can be stored (e.g., 3)
-
usb_host_client_event_cb_t client_event_callback
Client's event callback function
-
void *callback_arg
Event callback function argument
-
struct usb_host_client_config_t::[anonymous]::[anonymous] async
Async callback config
-
bool is_synchronous
Macros
-
USB_HOST_LIB_EVENT_FLAGS_NO_CLIENTS
All clients have been deregistered from the USB Host Library
-
USB_HOST_LIB_EVENT_FLAGS_ALL_FREE
The USB Host Library has freed all devices
Type Definitions
-
typedef struct usb_host_client_handle_s *usb_host_client_handle_t
Handle to a USB Host Library asynchronous client.
An asynchronous client can be registered using usb_host_client_register()
备注
Asynchronous API
-
typedef void (*usb_host_client_event_cb_t)(const usb_host_client_event_msg_t *event_msg, void *arg)
Client event callback.
Each client of the USB Host Library must register an event callback to receive event messages from the USB Host Library.
The client event callback is run from the context of the clients usb_host_client_handle_events() function
Enumerations
Header File
This header file can be included with:
#include "usb/usb_helpers.h"
This header file is a part of the API provided by the
usb
component. To declare that your component depends onusb
, add the following to your CMakeLists.txt:REQUIRES usb
or
PRIV_REQUIRES usb
Functions
-
const usb_standard_desc_t *usb_parse_next_descriptor(const usb_standard_desc_t *cur_desc, uint16_t wTotalLength, int *offset)
Get the next descriptor.
Given a particular descriptor within a full configuration descriptor, get the next descriptor within the configuration descriptor. This is a convenience function that can be used to walk each individual descriptor within a full configuration descriptor.
- 参数
cur_desc -- [in] Current descriptor
wTotalLength -- [in] Total length of the configuration descriptor
offset -- [inout] Byte offset relative to the start of the configuration descriptor. On input, it is the offset of the current descriptor. On output, it is the offset of the returned descriptor.
- 返回
usb_standard_desc_t* Next descriptor, NULL if end of configuration descriptor reached
-
const usb_standard_desc_t *usb_parse_next_descriptor_of_type(const usb_standard_desc_t *cur_desc, uint16_t wTotalLength, uint8_t bDescriptorType, int *offset)
Get the next descriptor of a particular type.
Given a particular descriptor within a full configuration descriptor, get the next descriptor of a particular type (i.e., using the bDescriptorType value) within the configuration descriptor.
- 参数
cur_desc -- [in] Current descriptor
wTotalLength -- [in] Total length of the configuration descriptor
bDescriptorType -- [in] Type of the next descriptor to get
offset -- [inout] Byte offset relative to the start of the configuration descriptor. On input, it is the offset of the current descriptor. On output, it is the offset of the returned descriptor.
- 返回
usb_standard_desc_t* Next descriptor, NULL if end descriptor is not found or configuration descriptor reached
-
int usb_parse_interface_number_of_alternate(const usb_config_desc_t *config_desc, uint8_t bInterfaceNumber)
Get the number of alternate settings for a bInterfaceNumber.
Given a particular configuration descriptor, for a particular bInterfaceNumber, get the number of alternate settings available for that interface (i.e., the max possible value of bAlternateSetting for that bInterfaceNumber).
- 参数
config_desc -- [in] Pointer to the start of a full configuration descriptor
bInterfaceNumber -- [in] Interface number
- 返回
int The number of alternate settings that the interface has, -1 if bInterfaceNumber not found
-
const usb_intf_desc_t *usb_parse_interface_descriptor(const usb_config_desc_t *config_desc, uint8_t bInterfaceNumber, uint8_t bAlternateSetting, int *offset)
Get a particular interface descriptor (using bInterfaceNumber and bAlternateSetting)
Given a full configuration descriptor, get a particular interface descriptor.
备注
To get the number of alternate settings for a particular bInterfaceNumber, call usb_parse_interface_number_of_alternate()
- 参数
config_desc -- [in] Pointer to the start of a full configuration descriptor
bInterfaceNumber -- [in] Interface number
bAlternateSetting -- [in] Alternate setting number
offset -- [out] Byte offset of the interface descriptor relative to the start of the configuration descriptor. Can be NULL.
- 返回
const usb_intf_desc_t* Pointer to interface descriptor, NULL if not found.
-
const usb_ep_desc_t *usb_parse_endpoint_descriptor_by_index(const usb_intf_desc_t *intf_desc, int index, uint16_t wTotalLength, int *offset)
Get an endpoint descriptor within an interface descriptor.
Given an interface descriptor, get the Nth endpoint descriptor of the interface. The number of endpoints in an interface is indicated by the bNumEndpoints field of the interface descriptor.
备注
If bNumEndpoints is 0, it means the interface uses the default endpoint only
- 参数
intf_desc -- [in] Pointer to thee start of an interface descriptor
index -- [in] Endpoint index
wTotalLength -- [in] Total length of the containing configuration descriptor
offset -- [inout] Byte offset relative to the start of the configuration descriptor. On input, it is the offset of the interface descriptor. On output, it is the offset of the endpoint descriptor.
- 返回
const usb_ep_desc_t* Pointer to endpoint descriptor, NULL if not found.
-
const usb_ep_desc_t *usb_parse_endpoint_descriptor_by_address(const usb_config_desc_t *config_desc, uint8_t bInterfaceNumber, uint8_t bAlternateSetting, uint8_t bEndpointAddress, int *offset)
Get an endpoint descriptor based on an endpoint's address.
Given a configuration descriptor, get an endpoint descriptor based on it's bEndpointAddress, bAlternateSetting, and bInterfaceNumber.
- 参数
config_desc -- [in] Pointer to the start of a full configuration descriptor
bInterfaceNumber -- [in] Interface number
bAlternateSetting -- [in] Alternate setting number
bEndpointAddress -- [in] Endpoint address
offset -- [out] Byte offset of the endpoint descriptor relative to the start of the configuration descriptor. Can be NULL
- 返回
const usb_ep_desc_t* Pointer to endpoint descriptor, NULL if not found.
-
void usb_print_device_descriptor(const usb_device_desc_t *devc_desc)
Print device descriptor.
- 参数
devc_desc -- [in] Device descriptor
-
void usb_print_config_descriptor(const usb_config_desc_t *cfg_desc, print_class_descriptor_cb class_specific_cb)
Print configuration descriptor.
This function prints the full contents of a configuration descriptor (including interface and endpoint descriptors)
When a non-standard descriptor is encountered, this function will call the class_specific_cb if it is provided
- 参数
cfg_desc -- [in] Configuration descriptor
class_specific_cb -- [in] Class specific descriptor callback. Can be NULL
-
void usb_print_string_descriptor(const usb_str_desc_t *str_desc)
Print a string descriptor.
This function will only print ASCII characters of the UTF-16 encoded string
- 参数
str_desc -- [in] String descriptor
-
static inline int usb_round_up_to_mps(int num_bytes, int mps)
Round up to an integer multiple of endpoint's MPS.
This is a convenience function to round up a size/length to an endpoint's MPS (Maximum packet size). This is useful when calculating transfer or buffer lengths of IN endpoints.
If MPS <= 0, this function will return 0
If num_bytes <= 0, this function will return 0
- 参数
num_bytes -- [in] Number of bytes
mps -- [in] MPS
- 返回
int Round up integer multiple of MPS
Type Definitions
-
typedef void (*print_class_descriptor_cb)(const usb_standard_desc_t*)
Print class specific descriptor callback.
Optional callback to be provided to usb_print_config_descriptor() function. The callback is called when when a non-standard descriptor is encountered. The callback should decode the descriptor as print it.
Header File
This header file can be included with:
#include "usb/usb_types_stack.h"
This header file is a part of the API provided by the
usb
component. To declare that your component depends onusb
, add the following to your CMakeLists.txt:REQUIRES usb
or
PRIV_REQUIRES usb
Structures
-
struct usb_parent_dev_info_t
Parent device information.
Public Members
-
usb_device_handle_t dev_hdl
Device's parent handle
-
uint8_t port_num
Device's parent port number
-
usb_device_handle_t dev_hdl
-
struct usb_device_info_t
Basic information of an enumerated device.
Public Members
-
usb_parent_dev_info_t parent
Device's parent information
-
usb_speed_t speed
Device's speed
-
uint8_t dev_addr
Device's address
-
uint8_t bMaxPacketSize0
The maximum packet size of the device's default endpoint
-
uint8_t bConfigurationValue
Device's current configuration number
-
const usb_str_desc_t *str_desc_manufacturer
Pointer to Manufacturer string descriptor (can be NULL)
-
const usb_str_desc_t *str_desc_product
Pointer to Product string descriptor (can be NULL)
-
const usb_str_desc_t *str_desc_serial_num
Pointer to Serial Number string descriptor (can be NULL)
-
usb_parent_dev_info_t parent
-
struct usb_isoc_packet_desc_t
Isochronous packet descriptor.
If the number of bytes in an Isochronous transfer is larger than the MPS of the endpoint, the transfer is split into multiple packets transmitted at the endpoint's specified interval. An array of Isochronous packet descriptors describes how an Isochronous transfer should be split into multiple packets.
Public Members
-
int num_bytes
Number of bytes to transmit/receive in the packet. IN packets should be integer multiple of MPS
-
int actual_num_bytes
Actual number of bytes transmitted/received in the packet
-
usb_transfer_status_t status
Status of the packet
-
int num_bytes
-
struct usb_transfer_s
USB transfer structure.
Public Members
-
uint8_t *const data_buffer
Pointer to data buffer
-
const size_t data_buffer_size
Size of the data buffer in bytes
-
int num_bytes
Number of bytes to transfer. Control transfers should include the size of the setup packet. Isochronous transfer should be the total transfer size of all packets. For non-control IN transfers, num_bytes should be an integer multiple of MPS.
-
int actual_num_bytes
Actual number of bytes transferred
-
uint32_t flags
Transfer flags
-
usb_device_handle_t device_handle
Device handle
-
uint8_t bEndpointAddress
Endpoint Address
-
usb_transfer_status_t status
Status of the transfer
-
uint32_t timeout_ms
Timeout (in milliseconds) of the packet (currently not supported yet)
-
usb_transfer_cb_t callback
Transfer callback
-
void *context
Context variable for transfer to associate transfer with something
-
const int num_isoc_packets
Only relevant to Isochronous. Number of service periods (i.e., intervals) to transfer data buffer over.
-
usb_isoc_packet_desc_t isoc_packet_desc[]
Descriptors for each Isochronous packet
-
uint8_t *const data_buffer
Macros
-
USB_TRANSFER_FLAG_ZERO_PACK
Terminate Bulk/Interrupt OUT transfer with a zero length packet.
OUT transfers normally terminate when the Host has transferred the exact amount of data it needs to the device. However, for bulk and interrupt OUT transfers, if the transfer size just happened to be a multiple of MPS, it will be impossible to know the boundary between two consecutive transfers to the same endpoint.
Therefore, this flag will cause the transfer to automatically add a zero length packet (ZLP) at the end of the transfer if the following conditions are met:
The target endpoint is a Bulk/Interrupt OUT endpoint (Host to device)
The transfer's length (i.e., transfer.num_bytes) is a multiple of the endpoint's MPS
Otherwise, this flag has no effect.
Users should check whether their target device's class requires a ZLP, as not all Bulk/Interrupt OUT endpoints require them. For example:
For MSC Bulk Only Transport class, the Host MUST NEVER send a ZLP. Bulk transfer boundaries are determined by the CBW and CSW instead
For CDC Ethernet, the Host MUST ALWAYS send a ZLP if a segment (i.e., a transfer) is a multiple of MPS (See 3.3.1 Segment Delineation)
备注
See USB2.0 specification 5.7.3 and 5.8.3 for more details
备注
IN transfers normally terminate when the Host as receive the exact amount of data it needs (must be multiple of MPS) or the endpoint sends a short packet to the Host (For bulk OUT only). Indicates that a bulk OUT transfers should always terminate with a short packet, even if it means adding an extra zero length packet
Type Definitions
-
typedef struct usb_device_handle_s *usb_device_handle_t
Handle of a USB Device connected to a USB Host.
-
typedef bool (*usb_host_enum_filter_cb_t)(const usb_device_desc_t *dev_desc, uint8_t *bConfigurationValue)
Enumeration filter callback.
This callback is called at the beginning of the enumeration process for a newly attached device. Through this callback, users are able to:
filter which devices should be enumerated
select the configuration number to use when enumerating the device
The device descriptor is passed to this callback to allow users to filter devices based on Vendor ID, Product ID, and class code.
- Attention
This callback must be non-blocking
- Attention
This callback must not submit any USB transfers
- Param dev_desc
[in] Device descriptor of the device to enumerate
- Param bConfigurationValue
[out] Configuration number to use when enumerating the device (starts with 1)
- Return
bool
true: USB device will be enumerated
false: USB device will not be enumerated
-
typedef struct usb_transfer_s usb_transfer_t
USB transfer structure.
This structure is used to represent a transfer from a software client to an endpoint over the USB bus. Some of the fields are made const on purpose as they are fixed on allocation. Users should call the appropriate USB Host Library function to allocate a USB transfer structure instead of allocating this structure themselves.
The transfer type is inferred from the endpoint this transfer is sent to. Depending on the transfer type, users should note the following:
Bulk: This structure represents a single bulk transfer. If the number of bytes exceeds the endpoint's MPS, the transfer will be split into multiple MPS sized packets followed by a short packet.
Control: This structure represents a single control transfer. This first 8 bytes of the data_buffer must be filled with the setup packet (see usb_setup_packet_t). The num_bytes field should be the total size of the transfer (i.e., size of setup packet + wLength).
Interrupt: Represents an interrupt transfer. If num_bytes exceeds the MPS of the endpoint, the transfer will be split into multiple packets, and each packet is transferred at the endpoint's specified interval.
Isochronous: Represents a stream of bytes that should be transferred to an endpoint at a fixed rate. The transfer is split into packets according to the each isoc_packet_desc. A packet is transferred at each interval of the endpoint. If an entire ISOC URB was transferred without error (skipped packets do not count as errors), the URB's overall status and the status of each packet descriptor will be updated, and the actual_num_bytes reflects the total bytes transferred over all packets. If the ISOC URB encounters an error, the entire URB is considered erroneous so only the overall status will updated.
备注
For Bulk/Control/Interrupt IN transfers, the num_bytes must be a integer multiple of the endpoint's MPS
备注
This structure should be allocated via usb_host_transfer_alloc()
备注
Once the transfer has be submitted, users should not modify the structure until the transfer has completed
-
typedef void (*usb_transfer_cb_t)(usb_transfer_t *transfer)
USB transfer completion callback.
Enumerations
-
enum usb_speed_t
USB Standard Speeds.
Values:
-
enumerator USB_SPEED_LOW
USB Low Speed (1.5 Mbit/s)
-
enumerator USB_SPEED_FULL
USB Full Speed (12 Mbit/s)
-
enumerator USB_SPEED_HIGH
USB High Speed (480 Mbit/s)
-
enumerator USB_SPEED_LOW
-
enum usb_transfer_type_t
The type of USB transfer.
备注
The enum values need to match the bmAttributes field of an EP descriptor
Values:
-
enumerator USB_TRANSFER_TYPE_CTRL
-
enumerator USB_TRANSFER_TYPE_ISOCHRONOUS
-
enumerator USB_TRANSFER_TYPE_BULK
-
enumerator USB_TRANSFER_TYPE_INTR
-
enumerator USB_TRANSFER_TYPE_CTRL
-
enum usb_transfer_status_t
The status of a particular transfer.
Values:
-
enumerator USB_TRANSFER_STATUS_COMPLETED
The transfer was successful (but may be short)
-
enumerator USB_TRANSFER_STATUS_ERROR
The transfer failed because due to excessive errors (e.g. no response or CRC error)
-
enumerator USB_TRANSFER_STATUS_TIMED_OUT
The transfer failed due to a time out
-
enumerator USB_TRANSFER_STATUS_CANCELED
The transfer was canceled
-
enumerator USB_TRANSFER_STATUS_STALL
The transfer was stalled
-
enumerator USB_TRANSFER_STATUS_OVERFLOW
The transfer as more data was sent than was requested
-
enumerator USB_TRANSFER_STATUS_SKIPPED
ISOC packets only. The packet was skipped due to system latency or bus overload
-
enumerator USB_TRANSFER_STATUS_NO_DEVICE
The transfer failed because the target device is gone
-
enumerator USB_TRANSFER_STATUS_COMPLETED
Header File
This header file can be included with:
#include "usb/usb_types_ch9.h"
This header file is a part of the API provided by the
usb
component. To declare that your component depends onusb
, add the following to your CMakeLists.txt:REQUIRES usb
or
PRIV_REQUIRES usb
Unions
-
union usb_setup_packet_t
- #include <usb_types_ch9.h>
Structure representing a USB control transfer setup packet.
See Table 9-2 of USB2.0 specification for more details
Public Members
-
uint8_t bmRequestType
Characteristics of request
-
uint8_t bRequest
Specific request
-
uint16_t wValue
Word-sized field that varies according to request
-
uint16_t wIndex
Word-sized field that varies according to request; typically used to pass an index or offset
-
uint16_t wLength
Number of bytes to transfer if there is a data stage
-
struct usb_setup_packet_t::[anonymous] USB_DESC_ATTR
USB descriptor attributes
-
uint8_t val[USB_SETUP_PACKET_SIZE]
Descriptor value
-
uint8_t bmRequestType
-
union usb_device_status_t
- #include <usb_types_ch9.h>
Structure representing a USB device status.
See Figures 9-4 Information Returned by a GetStatus() Request to a Device of USB2.0 specification for more details
Public Members
-
uint16_t self_powered
1 - Device is currently self-powered, 0 - bus powered
-
uint16_t remote_wakeup
1 - the ability of the device to signal remote wakeup is enabled, 0 - the ability of the device to signal remote wakeup is disabled.
-
uint16_t reserved
reserved
-
struct usb_device_status_t::[anonymous] USB_DESC_ATTR
Packed
-
uint16_t val
Device status value
-
uint16_t self_powered
-
union usb_standard_desc_t
- #include <usb_types_ch9.h>
USB standard descriptor.
All USB standard descriptors start with these two bytes. Use this type when traversing over configuration descriptors
Public Members
-
uint8_t bLength
Size of the descriptor in bytes
-
uint8_t bDescriptorType
Descriptor Type
-
struct usb_standard_desc_t::[anonymous] USB_DESC_ATTR
USB descriptor attributes
-
uint8_t val[USB_STANDARD_DESC_SIZE]
Descriptor value
-
uint8_t bLength
-
union usb_device_desc_t
- #include <usb_types_ch9.h>
Structure representing a USB device descriptor.
See Table 9-8 of USB2.0 specification for more details
Public Members
-
uint8_t bLength
Size of the descriptor in bytes
-
uint8_t bDescriptorType
DEVICE Descriptor Type
-
uint16_t bcdUSB
USB Specification Release Number in Binary-Coded Decimal (i.e., 2.10 is 210H)
-
uint8_t bDeviceClass
Class code (assigned by the USB-IF)
-
uint8_t bDeviceSubClass
Subclass code (assigned by the USB-IF)
-
uint8_t bDeviceProtocol
Protocol code (assigned by the USB-IF)
-
uint8_t bMaxPacketSize0
Maximum packet size for endpoint zero (only 8, 16, 32, or 64 are valid)
-
uint16_t idVendor
Vendor ID (assigned by the USB-IF)
-
uint16_t idProduct
Product ID (assigned by the manufacturer)
-
uint16_t bcdDevice
Device release number in binary-coded decimal
-
uint8_t iManufacturer
Index of string descriptor describing manufacturer
-
uint8_t iProduct
Index of string descriptor describing product
-
uint8_t iSerialNumber
Index of string descriptor describing the device’s serial number
-
uint8_t bNumConfigurations
Number of possible configurations
-
struct usb_device_desc_t::[anonymous] USB_DESC_ATTR
USB descriptor attributes
-
uint8_t val[USB_DEVICE_DESC_SIZE]
Descriptor value
-
uint8_t bLength
-
union usb_config_desc_t
- #include <usb_types_ch9.h>
Structure representing a short USB configuration descriptor.
See Table 9-10 of USB2.0 specification for more details
备注
The full USB configuration includes all the interface and endpoint descriptors of that configuration.
Public Members
-
uint8_t bLength
Size of the descriptor in bytes
-
uint8_t bDescriptorType
CONFIGURATION Descriptor Type
-
uint16_t wTotalLength
Total length of data returned for this configuration
-
uint8_t bNumInterfaces
Number of interfaces supported by this configuration
-
uint8_t bConfigurationValue
Value to use as an argument to the SetConfiguration() request to select this configuration
-
uint8_t iConfiguration
Index of string descriptor describing this configuration
-
uint8_t bmAttributes
Configuration characteristics
-
uint8_t bMaxPower
Maximum power consumption of the USB device from the bus in this specific configuration when the device is fully operational.
-
struct usb_config_desc_t::[anonymous] USB_DESC_ATTR
USB descriptor attributes
-
uint8_t val[USB_CONFIG_DESC_SIZE]
Descriptor value
-
uint8_t bLength
-
union usb_iad_desc_t
- #include <usb_types_ch9.h>
Structure representing a USB interface association descriptor.
Public Members
-
uint8_t bLength
Size of the descriptor in bytes
-
uint8_t bDescriptorType
INTERFACE ASSOCIATION Descriptor Type
-
uint8_t bFirstInterface
Interface number of the first interface that is associated with this function
-
uint8_t bInterfaceCount
Number of contiguous interfaces that are associated with this function
-
uint8_t bFunctionClass
Class code (assigned by USB-IF)
-
uint8_t bFunctionSubClass
Subclass code (assigned by USB-IF)
-
uint8_t bFunctionProtocol
Protocol code (assigned by USB-IF)
-
uint8_t iFunction
Index of string descriptor describing this function
-
struct usb_iad_desc_t::[anonymous] USB_DESC_ATTR
USB descriptor attributes
-
uint8_t val[USB_IAD_DESC_SIZE]
Descriptor value
-
uint8_t bLength
-
union usb_intf_desc_t
- #include <usb_types_ch9.h>
Structure representing a USB interface descriptor.
See Table 9-12 of USB2.0 specification for more details
Public Members
-
uint8_t bLength
Size of the descriptor in bytes
-
uint8_t bDescriptorType
INTERFACE Descriptor Type
-
uint8_t bInterfaceNumber
Number of this interface.
-
uint8_t bAlternateSetting
Value used to select this alternate setting for the interface identified in the prior field
-
uint8_t bNumEndpoints
Number of endpoints used by this interface (excluding endpoint zero).
-
uint8_t bInterfaceClass
Class code (assigned by the USB-IF)
-
uint8_t bInterfaceSubClass
Subclass code (assigned by the USB-IF)
-
uint8_t bInterfaceProtocol
Protocol code (assigned by the USB)
-
uint8_t iInterface
Index of string descriptor describing this interface
-
struct usb_intf_desc_t::[anonymous] USB_DESC_ATTR
USB descriptor attributes
-
uint8_t val[USB_INTF_DESC_SIZE]
Descriptor value
-
uint8_t bLength
-
union usb_ep_desc_t
- #include <usb_types_ch9.h>
Structure representing a USB endpoint descriptor.
See Table 9-13 of USB2.0 specification for more details
Public Members
-
uint8_t bLength
Size of the descriptor in bytes
-
uint8_t bDescriptorType
ENDPOINT Descriptor Type
-
uint8_t bEndpointAddress
The address of the endpoint on the USB device described by this descriptor
-
uint8_t bmAttributes
This field describes the endpoint’s attributes when it is configured using the bConfigurationValue.
-
uint16_t wMaxPacketSize
Maximum packet size this endpoint is capable of sending or receiving when this configuration is selected.
-
uint8_t bInterval
Interval for polling Isochronous and Interrupt endpoints. Expressed in frames or microframes depending on the device operating speed (1 ms for Low-Speed and Full-Speed or 125 us for USB High-Speed and above).
-
struct usb_ep_desc_t::[anonymous] USB_DESC_ATTR
USB descriptor attributes
-
uint8_t val[USB_EP_DESC_SIZE]
Descriptor value
-
uint8_t bLength
-
union usb_str_desc_t
- #include <usb_types_ch9.h>
Structure representing a USB string descriptor.
Macros
-
USB_DESC_ATTR
-
USB_B_DESCRIPTOR_TYPE_DEVICE
Descriptor types from USB2.0 specification table 9.5.
-
USB_B_DESCRIPTOR_TYPE_CONFIGURATION
-
USB_B_DESCRIPTOR_TYPE_STRING
-
USB_B_DESCRIPTOR_TYPE_INTERFACE
-
USB_B_DESCRIPTOR_TYPE_ENDPOINT
-
USB_B_DESCRIPTOR_TYPE_DEVICE_QUALIFIER
-
USB_B_DESCRIPTOR_TYPE_OTHER_SPEED_CONFIGURATION
-
USB_B_DESCRIPTOR_TYPE_INTERFACE_POWER
-
USB_B_DESCRIPTOR_TYPE_OTG
Descriptor types from USB 2.0 ECN.
-
USB_B_DESCRIPTOR_TYPE_DEBUG
-
USB_B_DESCRIPTOR_TYPE_INTERFACE_ASSOCIATION
-
USB_B_DESCRIPTOR_TYPE_SECURITY
Descriptor types from Wireless USB spec.
-
USB_B_DESCRIPTOR_TYPE_KEY
-
USB_B_DESCRIPTOR_TYPE_ENCRYPTION_TYPE
-
USB_B_DESCRIPTOR_TYPE_BOS
-
USB_B_DESCRIPTOR_TYPE_DEVICE_CAPABILITY
-
USB_B_DESCRIPTOR_TYPE_WIRELESS_ENDPOINT_COMP
-
USB_B_DESCRIPTOR_TYPE_WIRE_ADAPTER
-
USB_B_DESCRIPTOR_TYPE_RPIPE
-
USB_B_DESCRIPTOR_TYPE_CS_RADIO_CONTROL
-
USB_B_DESCRIPTOR_TYPE_PIPE_USAGE
Descriptor types from UAS specification.
-
USB_SETUP_PACKET_SIZE
Size of a USB control transfer setup packet in bytes.
-
USB_BM_REQUEST_TYPE_DIR_OUT
Bit masks belonging to the bmRequestType field of a setup packet.
-
USB_BM_REQUEST_TYPE_DIR_IN
-
USB_BM_REQUEST_TYPE_TYPE_STANDARD
-
USB_BM_REQUEST_TYPE_TYPE_CLASS
-
USB_BM_REQUEST_TYPE_TYPE_VENDOR
-
USB_BM_REQUEST_TYPE_TYPE_RESERVED
-
USB_BM_REQUEST_TYPE_TYPE_MASK
-
USB_BM_REQUEST_TYPE_RECIP_DEVICE
-
USB_BM_REQUEST_TYPE_RECIP_INTERFACE
-
USB_BM_REQUEST_TYPE_RECIP_ENDPOINT
-
USB_BM_REQUEST_TYPE_RECIP_OTHER
-
USB_BM_REQUEST_TYPE_RECIP_MASK
-
USB_B_REQUEST_GET_STATUS
Bit masks belonging to the bRequest field of a setup packet.
-
USB_B_REQUEST_CLEAR_FEATURE
-
USB_B_REQUEST_SET_FEATURE
-
USB_B_REQUEST_SET_ADDRESS
-
USB_B_REQUEST_GET_DESCRIPTOR
-
USB_B_REQUEST_SET_DESCRIPTOR
-
USB_B_REQUEST_GET_CONFIGURATION
-
USB_B_REQUEST_SET_CONFIGURATION
-
USB_B_REQUEST_GET_INTERFACE
-
USB_B_REQUEST_SET_INTERFACE
-
USB_B_REQUEST_SYNCH_FRAME
-
USB_W_VALUE_DT_DEVICE
Bit masks belonging to the wValue field of a setup packet.
-
USB_W_VALUE_DT_CONFIG
-
USB_W_VALUE_DT_STRING
-
USB_W_VALUE_DT_INTERFACE
-
USB_W_VALUE_DT_ENDPOINT
-
USB_W_VALUE_DT_DEVICE_QUALIFIER
-
USB_W_VALUE_DT_OTHER_SPEED_CONFIG
-
USB_W_VALUE_DT_INTERFACE_POWER
-
USB_SETUP_PACKET_INIT_GET_STATUS(setup_pkt_ptr)
Initializer for a GET_STATUS request.
Sets the address of a connected device
-
USB_SETUP_PACKET_INIT_SET_ADDR(setup_pkt_ptr, addr)
Initializer for a SET_ADDRESS request.
Sets the address of a connected device
-
USB_SETUP_PACKET_INIT_GET_DEVICE_DESC(setup_pkt_ptr)
Initializer for a request to get a device's device descriptor.
-
USB_SETUP_PACKET_INIT_GET_CONFIG(setup_pkt_ptr)
Initializer for a request to get a device's current configuration number.
-
USB_SETUP_PACKET_INIT_GET_CONFIG_DESC(setup_pkt_ptr, desc_index, desc_len)
Initializer for a request to get one of the device's current configuration descriptor.
desc_index indicates the configuration's index number
Number of bytes of the configuration descriptor to get
-
USB_SETUP_PACKET_INIT_SET_CONFIG(setup_pkt_ptr, config_num)
Initializer for a request to set a device's current configuration number.
-
USB_SETUP_PACKET_INIT_SET_INTERFACE(setup_pkt_ptr, intf_num, alt_setting_num)
Initializer for a request to set an interface's alternate setting.
-
USB_SETUP_PACKET_INIT_GET_STR_DESC(setup_pkt_ptr, string_index, lang_id, desc_len)
Initializer for a request to get an string descriptor.
-
USB_STANDARD_DESC_SIZE
Size of dummy USB standard descriptor.
-
USB_DEVICE_DESC_SIZE
Size of a USB device descriptor in bytes.
-
USB_CLASS_PER_INTERFACE
Possible base class values of the bDeviceClass field of a USB device descriptor.
-
USB_CLASS_AUDIO
-
USB_CLASS_COMM
-
USB_CLASS_HID
-
USB_CLASS_PHYSICAL
-
USB_CLASS_STILL_IMAGE
-
USB_CLASS_PRINTER
-
USB_CLASS_MASS_STORAGE
-
USB_CLASS_HUB
-
USB_CLASS_CDC_DATA
-
USB_CLASS_CSCID
-
USB_CLASS_CONTENT_SEC
-
USB_CLASS_VIDEO
-
USB_CLASS_WIRELESS_CONTROLLER
-
USB_CLASS_PERSONAL_HEALTHCARE
-
USB_CLASS_AUDIO_VIDEO
-
USB_CLASS_BILLBOARD
-
USB_CLASS_USB_TYPE_C_BRIDGE
-
USB_CLASS_MISC
-
USB_CLASS_APP_SPEC
-
USB_CLASS_VENDOR_SPEC
-
USB_SUBCLASS_VENDOR_SPEC
Vendor specific subclass code.
-
USB_CONFIG_DESC_SIZE
Size of a short USB configuration descriptor in bytes.
备注
The size of a full USB configuration includes all the interface and endpoint descriptors of that configuration.
-
USB_BM_ATTRIBUTES_ONE
Bit masks belonging to the bmAttributes field of a configuration descriptor.
Must be set
-
USB_BM_ATTRIBUTES_SELFPOWER
Self powered
-
USB_BM_ATTRIBUTES_WAKEUP
Can wake-up
-
USB_BM_ATTRIBUTES_BATTERY
Battery powered
-
USB_IAD_DESC_SIZE
Size of a USB interface association descriptor in bytes.
-
USB_INTF_DESC_SIZE
Size of a USB interface descriptor in bytes.
-
USB_EP_DESC_SIZE
Size of a USB endpoint descriptor in bytes.
-
USB_B_ENDPOINT_ADDRESS_EP_NUM_MASK
Bit masks belonging to the bEndpointAddress field of an endpoint descriptor.
-
USB_B_ENDPOINT_ADDRESS_EP_DIR_MASK
-
USB_W_MAX_PACKET_SIZE_MPS_MASK
Bit masks belonging to the wMaxPacketSize field of endpoint descriptor.
-
USB_W_MAX_PACKET_SIZE_MULT_MASK
-
USB_BM_ATTRIBUTES_XFERTYPE_MASK
Bit masks belonging to the bmAttributes field of an endpoint descriptor.
-
USB_BM_ATTRIBUTES_XFER_CONTROL
-
USB_BM_ATTRIBUTES_XFER_ISOC
-
USB_BM_ATTRIBUTES_XFER_BULK
-
USB_BM_ATTRIBUTES_XFER_INT
-
USB_BM_ATTRIBUTES_SYNCTYPE_MASK
-
USB_BM_ATTRIBUTES_SYNC_NONE
-
USB_BM_ATTRIBUTES_SYNC_ASYNC
-
USB_BM_ATTRIBUTES_SYNC_ADAPTIVE
-
USB_BM_ATTRIBUTES_SYNC_SYNC
-
USB_BM_ATTRIBUTES_USAGETYPE_MASK
-
USB_BM_ATTRIBUTES_USAGE_DATA
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USB_BM_ATTRIBUTES_USAGE_FEEDBACK
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USB_BM_ATTRIBUTES_USAGE_IMPLICIT_FB
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USB_EP_DESC_GET_XFERTYPE(desc_ptr)
Macro helpers to get information about an endpoint from its descriptor.
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USB_EP_DESC_GET_EP_NUM(desc_ptr)
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USB_EP_DESC_GET_EP_DIR(desc_ptr)
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USB_EP_DESC_GET_MPS(desc_ptr)
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USB_EP_DESC_GET_MULT(desc_ptr)
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USB_EP_DESC_GET_SYNCTYPE(desc_ptr)
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USB_EP_DESC_GET_USAGETYPE(desc_ptr)
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USB_STR_DESC_SIZE
Size of a short USB string descriptor in bytes.
Enumerations
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enum usb_device_state_t
USB2.0 device states.
See Table 9-1 of USB2.0 specification for more details
备注
The USB_DEVICE_STATE_NOT_ATTACHED is not part of the USB2.0 specification, but is a catch all state for devices that need to be cleaned up after a sudden disconnection or port error.
Values:
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enumerator USB_DEVICE_STATE_NOT_ATTACHED
The device was previously configured or suspended, but is no longer attached (either suddenly disconnected or a port error)
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enumerator USB_DEVICE_STATE_ATTACHED
Device is attached to the USB, but is not powered.
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enumerator USB_DEVICE_STATE_POWERED
Device is attached to the USB and powered, but has not been reset.
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enumerator USB_DEVICE_STATE_DEFAULT
Device is attached to the USB and powered and has been reset, but has not been assigned a unique address. Device responds at the default address.
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enumerator USB_DEVICE_STATE_ADDRESS
Device is attached to the USB, powered, has been reset, and a unique device address has been assigned. Device is not configured.
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enumerator USB_DEVICE_STATE_CONFIGURED
Device is attached to the USB, powered, has been reset, has a unique address, is configured, and is not suspended. The host may now use the function provided by the device.
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enumerator USB_DEVICE_STATE_SUSPENDED
Device is, at minimum, attached to the USB and is powered and has not seen bus activity for 3 ms. It may also have a unique address and be configured for use. However, because the device is suspended, the host may not use the device’s function.
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enumerator USB_DEVICE_STATE_NOT_ATTACHED
维护注意事项
备注
有关 USB 主机栈内部实现的更多细节,请参阅 USB Host Maintainers Notes (Introduction)。