通用usb驱动libusb介绍和使用示例
sudo insmod /lib/modules/2.6.22-14-generic/kernel/drivers/usb/serial/usbserial.ko vendor=0x8086 product=0xd001
同时插上ttyUSB0和ttyUSB1(ch341),obm可以将dkb下载下去,但是自动重起之后,就不能下载接下来的东西了,所以应该,需要close(ttyUSB0_handle);
然后进行接下来的下载,分别调用两次不过应该自动关闭了,所以可能还是不能同时插上ttyUSB0和ttyUSB1
lsusb 显示usb设备的vendor和product
比如:
b074@gliethttp:~$ lsusb
Bus 002 Device 001: ID 0000:0000
Bus 001 Device 116: ID 8086:d001 Intel Corp.
Bus 001 Device 003: ID 413c:2105 Dell Computer Corp.
Bus 001 Device 002: ID 0461:4d15 Primax Electronics, Ltd
Bus 001 Device 001: ID 0000:0000
其中Bus 001 Device 116: ID 8086:d001 Intel Corp. 就是vendor=0x8086和product=0xd001
可以使用dmesg来查看具体的是ttyUSB0还是ttyUSB1了
pidof hello.exe
pidof bash
显示进程的pid值
波特率:
#define B0 0000000 /* hang up */
#define B50 0000001
#define B75 0000002
#define B110 0000003
#define B134 0000004
#define B150 0000005
#define B200 0000006
#define B300 0000007
#define B600 0000010
#define B1200 0000011
#define B1800 0000012
#define B2400 0000013
#define B4800 0000014
#define B9600 0000015
#define B19200 0000016
#define B38400 0000017
#define EXTA B19200
#define EXTB B38400
#define CSIZE 0000060
#define CS5 0000000
#define CS6 0000020
#define CS7 0000040
#define CS8 0000060
#define CSTOPB 0000100
#define CREAD 0000200
#define PARENB 0000400
#define PARODD 0001000
#define HUPCL 0002000
#define CLOCAL 0004000
#define CBAUDEX 0010000
#define BOTHER 0010000
#define B57600 0010001
#define B115200 0010002
#define B230400 0010003
#define B460800 0010004 //有些CDMA使用该波特率
#define B500000 0010005
#define B576000 0010006
#define B921600 0010007
#define B1000000 0010010
#define B1152000 0010011
#define B1500000 0010012
#define B2000000 0010013
#define B2500000 0010014
#define B3000000 0010015
#define B3500000 0010016
#define B4000000 0010017
Developing Linux Device Drivers using Libusb API
Written by vikram_cvk - 2004-07-16 18:05
Introduction
We often come across a situation where a USB device which runs perfectly on Windows platform does not even get detected on Linux. Lack of support for USB devices is one of the reason why some people don't embrace Linux. Now there is a new API by name Libusb which helps the developers to develop USB device drivers on the fly!
What is Libusb
Libusb is a high-level language API which conceals low-level kernel interactions with the USB modules. It provides a set of function which are adequate to develop a device driver for a USB device from the Userspace.
Libusb is not complex
For any wannabe Linux Kernel programmers developing device driver as a Kernel module is a herculean task. Developing kernel modules requires fair degree of proficiency in 'C' language and also good idea of kernel subsystems, data structures etc. All these are enough to put-off a developer from venturing into Device Driver programming.Libusb has been designed to address this shortcoming. Simplified interface allows developers to develop USB drivers from the userspace . Libusb library functions provide high level abstraction to the Kernel structures and allows the developers to have access to these structures through the USBFS(USBfilesystem).
Its Cross-platform
Beauty of Libusb lies in its cross platform functionality. Driver written for one platform could be easily ported onto another platform with little or no changes, currently following operating systems are supported by Libusb.
Linux
FreeBSD
Darwin
OS X
This HOWTO focuses on how Libusb can be used on Linux platform. For information about other platforms goto http://http://libusb.sourceforge.net/.
LIBUSB ON LINUX
Linux is the most popular platform for the Libusb API,the reason being growing popularity of Linux as a stable OS. On Linux Libusb makes of the USBFS file system. by default USBFS is automatically mounted when the system is booted.
What is USBFS
USBFS is a filesystem specifically designed for USB devices, by default this filesystem gets mounted when the system is booted and it can be found at /proc/bus/usb/. This filesystem consists of information about all the USB devices that are connected to the computer.Libusb makes use of this filesystem to interact with the USB devices.
Following C program can be a stepping stone into the world of Libusb.This program can be used to gather all the technical/hardware details of a USB device connected to the computer ,ensure that some USB device is connected into the USB port.
Details like Vendor-Id , Product-Id ,Endpoint addresses of a USB device is of paramount importance for a device driver developer.
/* testlibusb.c */
#include
#include
void print_endpoint(struct usb_endpoint_descriptor *endpoint)
{
printf(" bEndpointAddress: %02xh\n", endpoint->bEndpointAddress);
printf(" bmAttributes: %02xh\n", endpoint->bmAttributes);
printf(" wMaxPacketSize: %d\n", endpoint->wMaxPacketSize);
printf(" bInterval: %d\n", endpoint->bInterval);
printf(" bRefresh: %d\n", endpoint->bRefresh);
printf(" bSynchAddress: %d\n", endpoint->bSynchAddress);
}
void print_altsetting(struct usb_interface_descriptor *interface)
{
int i;
printf(" bInterfaceNumber: %d\n", interface->bInterfaceNumber);
printf(" bAlternateSetting: %d\n", interface->bAlternateSetting);
printf(" bNumEndpoints: %d\n", interface->bNumEndpoints);
printf(" bInterfaceClass: %d\n", interface->bInterfaceClass);
printf(" bInterfaceSubClass: %d\n", interface->bInterfaceSubClass);
printf(" bInterfaceProtocol: %d\n", interface->bInterfaceProtocol);
printf(" iInterface: %d\n", interface->iInterface);
for (i = 0; i < interface->bNumEndpoints; i++)
print_endpoint(&interface->endpoint);
}
void print_interface(struct usb_interface *interface)
{
int i;
for (i = 0; i < interface->num_altsetting; i++)
print_altsetting(&interface->altsetting);
}
void print_configuration(struct usb_config_descriptor *config)
{
int i;
printf(" wTotalLength: %d\n", config->wTotalLength);
printf(" bNumInterfaces: %d\n", config->bNumInterfaces);
printf(" bConfigurationValue: %d\n", config->bConfigurationValue);
printf(" iConfiguration: %d\n", config->iConfiguration);
printf(" bmAttributes: %02xh\n", config->bmAttributes);
printf(" MaxPower: %d\n", config->MaxPower);
for (i = 0; i < config->bNumInterfaces; i++)
print_interface(&config->interface);
}
int main(void)
{
struct usb_bus *bus;
struct usb_device *dev;
usb_init();
usb_find_busses();
usb_find_devices();
printf("bus/device idVendor/idProduct\n");
for (bus = usb_busses; bus; bus = bus->next) {
for (dev = bus->devices; dev; dev = dev->next) {
int ret, i;
char string[256];
usb_dev_handle *udev;
printf("%s/%s %04X/%04X\n", bus->dirname, dev->filename,
dev->descriptor.idVendor, dev->descriptor.idProduct);
udev = usb_open(dev);
if (udev) {
if (dev->descriptor.iManufacturer) {
ret = usb_get_string_simple(udev, dev->descriptor.iManufacturer, string, sizeof(string));
if (ret > 0)
printf("- Manufacturer : %s\n", string);
else
printf("- Unable to fetch manufacturer string\n");
}
if (dev->descriptor.iProduct) {
ret = usb_get_string_simple(udev, dev->descriptor.iProduct, string, sizeof(string));
if (ret > 0)
printf("- Product : %s\n", string);
else
printf("- Unable to fetch product string\n");
}
if (dev->descriptor.iSerialNumber) {
ret = usb_get_string_simple(udev, dev->descriptor.iSerialNumber, string, sizeof(string));
if (ret > 0)
printf("- Serial Number: %s\n", string);
else
printf("- Unable to fetch serial number string\n");
}
usb_close (udev);
}
if (!dev->config) {
printf(" Couldn't retrieve descriptors\n");
continue;
}
for (i = 0; i < dev->descriptor.bNumConfigurations; i++)
print_configuration(&dev->config);
}
}
return 0;
}
The above program should be compiled as
(root$)gcc -o usbdevice_details testlibusb.c -I/usr/local/include -L. -lnsl -lm -lc -L/usr/local/lib -lusb
(root$)./usbdevice_details (enter)
Following is the output of the above command ,its the listing of a USB pen drive connected to my system.
The first line displays the bus-name/device-name & device-id/product-id and rest of the listing is self-descriptive.
001/004 0EA0/2168
- Manufacturer : USB
- Product : Flash Disk
- Serial Number: 4CE45C4E403EE53D
wTotalLength: 39
bNumInterfaces: 1
bConfigurationValue: 1
iConfiguration: 0
bmAttributes: 80h
MaxPower: 100
bInterfaceNumber: 0
bAlternateSetting: 0
bNumEndpoints: 3
bInterfaceClass: 8
bInterfaceSubClass: 6
bInterfaceProtocol: 80
iInterface: 0
bEndpointAddress: 81h
bmAttributes: 02h
wMaxPacketSize: 64
bInterval: 0
bRefresh: 0
bSynchAddress: 0
bEndpointAddress: 02h
bmAttributes: 02h
wMaxPacketSize: 64
bInterval: 0
bRefresh: 0
bSynchAddress: 0
bEndpointAddress: 83h
bmAttributes: 03h
wMaxPacketSize: 2
bInterval: 1
bRefresh: 0
bSynchAddress: 0
Before executing the above program download the current version of Libusb library from, http://http://libusb.sourceforge.net/. The above program can also be found under the tests directory of Libusb directory (after u install it)
Now I will explain in brief some of the functions and attributes dealt in the above program.
usb_init() - Used to initialize Libusb and establish connection with kernel structures .
usb_find_busses() - Looks for all the USB busses on the computer.
usb_find_devices() - Looks for all the USB devices connected to the computer.
usb_open(dev) - Opens the device 'dev' which is given as argument to this function.
usb_get_string_simple() - Used to extract the string descriptor of the device taken argument.
Important attributes of USB devices useful in device driver coding
Configuration and Endpoints are one of the two important descriptors of any USB device. These descriptors are defined using the ?struct usb_config_descriptor? and ?struct_usb_endpoint_descriptor? respectively .
dev->descriptor.idVendor ? Reveals the Vendor-Id of the USB device connected to the system.
dev->descriptor.idProduct - Reveals the Product-Id of the USB device connected to the system.
dev->descriptor.iManufacturer - Reveals the name of the Manufacturer USB device connected to the system.
EndpointAddress:Combination of endpoint address and endpoint direction on a USB device.
InterfaceNumber : One of the several interfaces that is allocated to the connected USB device.
AlternateSetting:This is part of the a single interface allocated to the USB device.
Prerequisites for Libusb programming
Linux system with Kernel 2.4 above series.
Proficiency in C language.
Good understanding of USB device internals.
Idea about USBFS.
Hope this HOWTO has enlightened you about Libusb API and I expect this HOWTO will give you a head start in your device driver programming endeavor .This HOWTO is just an introduction to Libusb ,for complete documentation please goto http://http://libusb.sourceforge.net/
About Myself
My name is Vikram C , I'm a linux freak and currently working as Linux developer in the city of Hyderabad India.You can reach me at vikram_147@hotmail.com / vikram@asrttechnologies.com
//================================================
驱动开发向来是内核开发中工作量最多的一块,随着USB设备的普及,大量的USB设备的驱动开发也成为驱动开发者手头上做的最多的事情。本文主要介绍 Linux平台下基于libusb的驱动开发,希望能够给从事Linux驱动开发的朋友带来些帮助,更希望能够给其他平台上的无驱设计带来些帮助。文章是我在工作中使用libusb的一些总结,难免有错误,如有不当的地方,还请指正。
Linux 平台上的usb驱动开发,主要有内核驱动的开发和基于libusb的无驱设计。
对于内核驱动的大部分设备,诸如带usb接口的hid设备,linux本身已经自带了相关的驱动,我们只要操作设备文件便可以完成对设备大部分的操作,而另外一些设备,诸如自己设计的硬件产品,这些驱动就需要我们驱动工程师开发出相关的驱动了。内核驱动有它的优点,然而内核驱动在某些情况下会遇到如下的一些问题:
1 当使用我们产品的客户有2.4内核的平台,同时也有2.6内核的平台,我们要设计的驱动是要兼容两个平台的,就连makefile 我们都要写两个。
2 当我们要把linux移植到嵌入平台上,你会发现原先linux自带的驱动移过去还挺大的,我的内核当然是越小越好拉,这样有必要么。这还不是最郁闷的地方,如果嵌入平台是客户的,客户要购买你的产品,你突然发现客户设备里的系统和你的环境不一样,它没有你要的驱动了,你的程序运行不了,你会先想:“没关系,我写个内核驱动加载一下不就行了“。却发现客户连insmod加载模块的工具都没移植,那时你就看看老天,说声我怎么那么倒霉啊,客户可不想你动他花了n时间移植的内核哦
3 花了些功夫写了个新产品的驱动,挺有成就感啊,代码质量也是相当的有水准啊。正当你沉醉在你的代码中时,客服不断的邮件来了,“客户需要2.6.5内核的驱动,config文件我已经发你了” “客户需要双核的 2.6.18-smp 的驱动” “客户的平台是自己定制的是2.6.12-xxx “ 你恨不得把驱动的源代码给客户,这样省得编译了。你的一部分工作时间编译内核,定制驱动
有问题产生必然会有想办法解决问题的人, libusb的出现给我们带来了某些方便,即节约了我们的时间,也降低了公司的成本。 所以在一些情况下,就可以考虑使用libusb的无驱设计了。
下面我们就来详细讨论一下libusb, 并以写一个hid设备的驱动来讲解如何运用libusb,至于文章中涉及的usb协议的知识,限于篇幅,就不详细讲解了,相关的可自行查看usb相关协议。
一 libusb 介绍
libusb 设计了一系列的外部API 为应用程序所调用,通过这些API应用程序可以操作硬件,从libusb的源代码可以看出,这些API 调用了内核的底层接口,和kernel driver中所用到的函数所实现的功能差不多,只是libusb更加接近USB 规范。使得libusb的使用也比开发内核驱动相对容易的多。
Libusb 的编译安装请查看Readme,这里不做详解
二 libusb 的外部接口
2.1 初始化设备接口
这些接口也可以称为核心函数,它们主要用来初始化并寻找相关设备。
usb_init
函数定义: void usb_init(void);
从函数名称可以看出这个函数是用来初始化相关数据的,这个函数大家只要记住必须调用就行了,而且是一开始就要调用的.
usb_find_busses
函数定义: int usb_find_busses(void);
寻找系统上的usb总线,任何usb设备都通过usb总线和计算机总线通信。进而和其他设备通信。此函数返回总线数。
usb_find_devices
函数定义: int usb_find_devices(void);
寻找总线上的usb设备,这个函数必要在调用usb_find_busses()后使用。以上的三个函数都是一开始就要用到的,此函数返回设备数量。
usb_get_busses
函数定义: struct usb_bus *usb_get_busses(void);
这个函数返回总线的列表,在高一些的版本中已经用不到了,这在下面的实例中会有讲解
2.2 操作设备接口
usb_open
函数定义: usb_dev_handle *usb_open(struct *usb_device dev);
打开要使用的设备,在对硬件进行操作前必须要调用usb_open 来打开设备,这里大家看到有两个结构体 usb_dev_handle 和 usb_device 是我们在开发中经常碰到的,有必要把它们的结构看一看。在libusb 中的usb.h和usbi.h中有定义。
这里我们不妨理解为返回的 usb_dev_handle 指针是指向设备的句柄,而行参里输入就是需要打开的设备。
usb_close
函数定义: int usb_close(usb_dev_handle *dev);
与usb_open相对应,关闭设备,是必须调用的, 返回0成功,<0 失败。
usb_set_configuration
函数定义: int usb_set_configuration(usb_dev_handle *dev, int configuration);
设置当前设备使用的configuration,参数configuration 是你要使用的configurtation descriptoes中的bConfigurationValue, 返回0成功,<0失败( 一个设备可能包含多个configuration,比如同时支持高速和低速的设备就有对应的两个configuration,详细可查看usb标准)
usb_set_altinterface
函数定义: int usb_set_altinterface(usb_dev_handle *dev, int alternate);
和名字的意思一样,此函数设置当前设备配置的interface descriptor,参数alternate是指interface descriptor中的bAlternateSetting。返回0成功,<0失败
usb_resetep
函数定义: int usb_resetep(usb_dev_handle *dev, unsigned int ep);
复位指定的endpoint,参数ep 是指bEndpointAddress,。这个函数不经常用,被下面介绍的usb_clear_halt函数所替代。
usb_clear_halt
函数定义: int usb_clear_halt (usb_dev_handle *dev, unsigned int ep);
复位指定的endpoint,参数ep 是指bEndpointAddress。这个函数用来替代usb_resetep
usb_reset
函数定义: int usb_reset(usb_dev_handle *dev);
这个函数现在基本不怎么用,不过这里我也讲一下,和名字所起的意思一样,这个函数reset设备,因为重启设备后还是要重新打开设备,所以用usb_close就已经可以满足要求了。
usb_claim_interface
函数定义: int usb_claim_interface(usb_dev_handle *dev, int interface);
注册与操作系统通信的接口,这个函数必须被调用,因为只有注册接口,才能做相应的操作。
Interface 指 bInterfaceNumber. (下面介绍的usb_release_interface 与之相对应,也是必须调用的函数)
usb_release_interface
函数定义: int usb_release_interface(usb_dev_handle *dev, int interface);
注销被usb_claim_interface函数调用后的接口,释放资源,和usb_claim_interface对应使用。
2.3 控制传输接口
usb_control_msg
函数定义:int usb_control_msg(usb_dev_handle *dev, int requesttype, int request, int value, int index, char *bytes, int size, int timeout);
从默认的管道发送和接受控制数据
usb_get_string
函数定义: int usb_get_string(usb_dev_handle *dev, int index, int langid, char *buf, size_t buflen);
usb_get_string_simple
函数定义: int usb_get_string_simple(usb_dev_handle *dev, int index, char *buf, size_t buflen);
usb_get_descriptor
函数定义: int usb_get_descriptor(usb_dev_handle *dev, unsigned char type, unsigned char index, void *buf, int size);
usb_get_descriptor_by_endpoint
函数定义: int usb_get_descriptor_by_endpoint(usb_dev_handle *dev, int ep, unsigned char type, unsigned char index, void *buf, int size);
2.4 批传输接口
usb_bulk_write
函数定义: int usb_bulk_write(usb_dev_handle *dev, int ep, char *bytes, int size, int timeout);
usb_interrupt_read
函数定义: int usb_interrupt_read(usb_dev_handle *dev, int ep, char *bytes, int size, int timeout);
2.5 中断传输接口
usb_bulk_write
函数定义: int usb_bulk_write(usb_dev_handle *dev, int ep, char *bytes, int size, int timeout);
usb_interrupt_read
函数定义: int usb_interrupt_read(usb_dev_handle *dev, int ep, char *bytes, int size, int timeout);
基本上libusb所经常用到的函数就有这些了,和usb协议确实很接近吧。下面我们实例在介绍一个应用。
//----------------===================================
#include <usb.h>
/* usb.h
这个头文件是要包括的,里面包含了必须要用到的数据结构
*/
/*
我们将一个设备的属性用一个结构体来概括
*/
typedef struct
{
struct usb_device* udev;
usb_dev_handle* device_handle;
/*
这里可以添加设备的其他属性,这里只列出每个设备要用到的属性
*/
} device_descript;
/*
用来设置传输数据的时间延迟
*/
#define USB_TIMEOUT 10000
/*
厂家
ID
和产品
ID */
#define VENDOR_ID 0xffff
#define PRODUCT_ID 0xffff
/*
这里定义数组来保存设备的相关属性,
DEVICE_MINOR
可以设置能够同时操作的设备数量,用全局变量的目的在于方便保存属性
*/
#define DEVICE_MINOR 16
int g_num;
device_descript g_list[ DEVICE_MINOR ];
/*
我们写个设备先找到设备,并把相关信息保存在
g_list
中
*/
int Device_Find()
{
struct usb_bus *bus;
struct usb_device *dev;
g_num = 0;
usb_find_busses();
usb_find_devices();
/*
寻找设备
*/
for (bus = usb_busses; bus; bus = bus->next) {
for (dev = bus->devices; dev; dev = dev->next) {
if(dev->descriptor.idVendor==VENDOR_ID&& dev->descriptor.idProduct == PRODUCT_ID) {
/*
保存设备信息
*/
if (g_num < DEVICE_MINOR) {
g_list[g_num].udev = dev;
g_num ++;
}
}
}
}
return g_num;
}
/*
找到设备后,我们根据信息打开设备
*/
int Device_Open()
{
/*
根据情况打开你所需要操作的设备,这里我们仅列出伪代码
*/
if(g_list[g_num].udev != NULL) {
g_list[g_num].device_handle = usb_open(g_list[g_num].udev);
}
}
/*
下面就是操作设备的函数了,我们就不列出来拉,大家可以参考上面的介绍
*/
int DeviceWite(int handle)
{
/*
填写相关代码,具体查看设备协议
*/
}
int DeviceOpen(int handle)
{
/*
填写相关代码,具体查看设备协议
*/
}
/*
最后不要忘记关闭设备
*/
void Device_close(int handle)
{
/*
调用
usb_close */
}