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linux系统下标准GPIO按键驱动

时间:2014-11-28 01:01:17      阅读:568      评论:0      收藏:0      [点我收藏+]

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前言:

  linux下platform平台驱动是为了方便隔离bsp与driver,利于移植。体现好代码的高内聚,低耦合。Linux设备驱动模型中,关心总线,设备和驱动三个实体。总线将设备和驱动绑定。在系统每注册一个设备的时候,都会寻找与之相匹配的驱动,相反的,每加载一个驱动的时候,也会寻找与之匹配的设备。匹配由总线完成。linux发明了一种虚拟的总线,称之为platform总线,相应的设备称之为platform_device,驱动为platform_driver。

  基于这个模型,又根据面向对象的思想,同一类的事物定义为一个基类。因此在驱动中,将同一基类的驱动,再抽象一个核心层。因此又分为了input设备,I2C设备,SPI设备等驱动。我们今天说的标准按键驱动,就是基于input输入设备。

 

正题:

  在内核中,按键的驱动已经完成!!!不需要我们自己写。driver/input/keyboard/gpio_keys.c 就是驱动文件。刚才说了,有驱动,还要有设备啊~只有这两个匹配了,只有这样我们才能在应用层操作这个设备。这个设备我们在哪注册呢?一般的,在板级的初始化c文件里面。比如:board_max6q_sabresd.c。这里面我们怎么搞呢?看下面::::::

 1 #if defined(CONFIG_KEYBOARD_GPIO) || defined(CONFIG_KEYBOARD_GPIO_MODULE)
 2 #define GPIO_BUTTON(gpio_num, ev_code, act_low, descr, wake, debounce)     3 {                                 4     .gpio        = gpio_num,                 5     .type        = EV_KEY,                 6     .code        = ev_code,                 7     .active_low    = act_low,                 8     .desc        = "btn " descr,                 9     .wakeup        = wake,                    10     .debounce_interval = debounce,                11 }
12 
13 static struct gpio_keys_button imx6q_buttons[] = {
14     GPIO_BUTTON(SABRESD_KEY_USER1, KEY_VOLUMEUP, 1, "user-key-1", 0, 1),
15     GPIO_BUTTON(SABRESD_KEY_USER2, KEY_VOLUMEDOWN, 1, "user-key-2", 0, 1),
16     GPIO_BUTTON(SABRESD_KEY_WHIBUSB, KEY_F1, 1, "whibusb", 0, 1),
17     GPIO_BUTTON(SABRESD_KEY_WHIBUSL, KEY_F2, 1, "whibusl", 0, 1),
18     GPIO_BUTTON(SABRESD_KEY_WHIBUSR, KEY_F3, 1, "whibusr", 0, 1),
19 };
20 
21 static struct gpio_keys_platform_data imx6q_button_data = {
22     .buttons    = imx6q_buttons,
23     .nbuttons    = ARRAY_SIZE(imx6q_buttons),
24 };
25 
26 static struct platform_device imx6q_button_device = {
27     .name        = "gpio-keys",
28     .id        = -1,
29     .num_resources  = 0,
30     .dev        = {
31         .platform_data = &imx6q_button_data,
32     }
33 };
34 
35 static void __init imx6q_add_device_buttons(void)
36 {
37     platform_device_register(&imx6q_button_device);
38 }
39 #else
40 static void __init imx6q_add_device_buttons(void) {}
41 #endif

上面注册了5个按键设备。然后在board_init()初始化函数里面,添加imx6q_add_device_buttons()。我们就可以通过应用层操作了。比如:按下某个按键的时候,在read()函数中获取哪个键被按下。下面的链接360无死角的gpio按键应用。注意的是/dev/input/eventX不太一样,操作的时候可以cat /proc/bus/input/devices查看一下咱们的按键是哪个event。

  看看上面的代码,依葫芦画瓢就可以完成GPIO按键的设备添加。接下来我们分析下驱动,能用了,最好还是明白下原理。

  跟网上其他的差不多,我们着重分析两个函数:

  

  1 static int __devinit gpio_keys_probe(struct platform_device *pdev)
  2 {
  3     struct gpio_keys_platform_data *pdata = pdev->dev.platform_data;    //相关的结构体以及宏定义在本c文件和include/linux/input.h include/linux/gpio_keys.h里面找。
  4     struct gpio_keys_drvdata *ddata;
  5     struct device *dev = &pdev->dev;
  6     struct input_dev *input;
  7     int i, error;
  8     int wakeup = 0;
  9   
10 ddata = kzalloc(sizeof(struct gpio_keys_drvdata) +    //分配且清空数据空间 11 pdata->nbuttons * sizeof(struct gpio_button_data), 12 GFP_KERNEL); 13 input = input_allocate_device();    //分配一个input设备 14 if (!ddata || !input) { 15 dev_err(dev, "failed to allocate state\n"); 16 error = -ENOMEM; 17 goto fail1; 18 } 19     //设置input设备属性
20
ddata->input = input;    
21 ddata->n_buttons = pdata->nbuttons; 22 ddata->enable = pdata->enable; 23 ddata->disable = pdata->disable; 24 mutex_init(&ddata->disable_lock); 25 26 platform_set_drvdata(pdev, ddata); 27 input_set_drvdata(input, ddata); 28 29 input->name = pdata->name ? : pdev->name; 30 input->phys = "gpio-keys/input0"; 31 input->dev.parent = &pdev->dev; 32 input->open = gpio_keys_open; 33 input->close = gpio_keys_close; 34 35 input->id.bustype = BUS_HOST; 36 input->id.vendor = 0x0001; 37 input->id.product = 0x0001; 38 input->id.version = 0x0100; 39 40 /* Enable auto repeat feature of Linux input subsystem */ 41 if (pdata->rep) 42 __set_bit(EV_REP, input->evbit); 43 44 for (i = 0; i < pdata->nbuttons; i++) {    //对注册的每个gpio进行设置 45 struct gpio_keys_button *button = &pdata->buttons[i]; 46 struct gpio_button_data *bdata = &ddata->data[i]; 47 unsigned int type = button->type ?: EV_KEY; 48 49 bdata->input = input; 50 bdata->button = button; 51 52 error = gpio_keys_setup_key(pdev, bdata, button);    //这个是具体实现,下面分析 53 if (error) 54 goto fail2; 55 56 if (button->wakeup) 57 wakeup = 1; 58      /*设置设备对事件的支持,比如设置对键1和键2的支持*/ 59 input_set_capability(input, type, button->code); 60 } 61   //创建文件系统的节点,可以网上搜搜看,好像我之前的博文也有写到这块 62 error = sysfs_create_group(&pdev->dev.kobj, &gpio_keys_attr_group); 63 if (error) { 64 dev_err(dev, "Unable to export keys/switches, error: %d\n", 65 error); 66 goto fail2; 67 } 68   //注册一个input设备 69 error = input_register_device(input); 70 if (error) { 71 dev_err(dev, "Unable to register input device, error: %d\n", 72 error); 73 goto fail3; 74 } 75 76 /* get current state of buttons */ 77 for (i = 0; i < pdata->nbuttons; i++) 78 gpio_keys_report_event(&ddata->data[i]); 79 input_sync(input); 80 81 device_init_wakeup(&pdev->dev, wakeup); 82 83 return 0; 84 85 fail3: 86 sysfs_remove_group(&pdev->dev.kobj, &gpio_keys_attr_group); 87 fail2: 88 while (--i >= 0) { 89 free_irq(gpio_to_irq(pdata->buttons[i].gpio), &ddata->data[i]); 90 if (ddata->data[i].timer_debounce) 91 del_timer_sync(&ddata->data[i].timer); 92 cancel_work_sync(&ddata->data[i].work); 93 gpio_free(pdata->buttons[i].gpio); 94 } 95 96 platform_set_drvdata(pdev, NULL); 97 fail1: 98 input_free_device(input); 99 kfree(ddata); 100 101 return error; 102 }

上面是probe函数的一些简要说明,probe顾名思义,就是探测到设备注册时,驱动完成的工作。

下面的函数是probe里面重要的gpio_keys_setup_key()函数

 1 static int __devinit gpio_keys_setup_key(struct platform_device *pdev,
 2                      struct gpio_button_data *bdata,
 3                      struct gpio_keys_button *button)
 4 {
 5     const char *desc = button->desc ? button->desc : "gpio_keys";
 6     struct device *dev = &pdev->dev;
 7     unsigned long irqflags;
 8     int irq, error;
 9 
10     setup_timer(&bdata->timer, gpio_keys_timer, (unsigned long)bdata);
11     INIT_WORK(&bdata->work, gpio_keys_work_func);
12 
13     error = gpio_request(button->gpio, desc);
14     if (error < 0) {
15         dev_err(dev, "failed to request GPIO %d, error %d\n",
16             button->gpio, error);
17         goto fail2;
18     }
19 
20     error = gpio_direction_input(button->gpio);
21     if (error < 0) {
22         dev_err(dev, "failed to configure"
23             " direction for GPIO %d, error %d\n",
24             button->gpio, error);
25         goto fail3;
26     }
27 
28     if (button->debounce_interval) {
29         error = gpio_set_debounce(button->gpio,
30                       button->debounce_interval * 1000);
31         /* use timer if gpiolib doesn‘t provide debounce */
32         if (error < 0)
33             bdata->timer_debounce = button->debounce_interval;
34     }
35 
36     irq = gpio_to_irq(button->gpio);
37     if (irq < 0) {
38         error = irq;
39         dev_err(dev, "Unable to get irq number for GPIO %d, error %d\n",
40             button->gpio, error);
41         goto fail3;
42     }
43 
44     irqflags = IRQF_TRIGGER_RISING | IRQF_TRIGGER_FALLING;
45     /*
46      * If platform has specified that the button can be disabled,
47      * we don‘t want it to share the interrupt line.
48      */
49     if (!button->can_disable)
50         irqflags |= IRQF_SHARED;
51     /*
52      * If platform has specified that the button can wake up the system,
53      * for example, the power key which usually use to wake up the system
54      * from suspend, we add the IRQF_EARLY_RESUME flag to this irq, so
55      * that the power key press can be handled and reported as early as
56      * possible. Some platform like Android need to get the power key
57      * event early to reume some devcies like framebuffer and etc.
58      */
59     if (button->wakeup)
60         irqflags |= IRQF_EARLY_RESUME;
61 
62     error = request_any_context_irq(irq, gpio_keys_isr, irqflags, desc, bdata);
63     if (error < 0) {
64         dev_err(dev, "Unable to claim irq %d; error %d\n",
65             irq, error);
66         goto fail3;
67     }
68 
69     return 0;
70 
71 fail3:
72     gpio_free(button->gpio);
73 fail2:
74     return error;
75 }

主要是gpio的中断,定时器,工作队列等设置。没什么大问题。具体函数不懂,碰到一个查一个。

代分析码相对简单困了回去睡觉了。

 

参考:

  GPIO按键的应用参考:http://gofayao.blog.163.com/blog/static/147305254201491631157686/

  驱动代码分析:http://www.linuxidc.com/Linux/2011-11/47650p3.htm

谢谢!

linux系统下标准GPIO按键驱动

标签:des   android   style   blog   http   io   ar   color   os   

原文地址:http://www.cnblogs.com/cyc2009/p/4127496.html

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