通过风扇FG脚检测风扇转速

1、概述

    通过风扇FG脚获取风扇转速。

2、分析

通过风扇FG脚检测风扇转速

    根据风扇规格书可知风扇风速=60/(2*脉冲周期),周期T=1/频率。那么我们需要获取FG脚上的脉冲频率,即可获取风扇风速。

3、解决方法

    利用边沿触发中断利用定时器获取1s进入中断的次数即可获取脉冲频率。

(1)注册检测脚

gpio-pwms {
		compatible = "gpio-pwms";
		pinctrl-names = "default";
		pwm1 {
			label = "pwm1";
			gpios = <&pio 0 6 GPIO_ACTIVE_HIGH>;
			gpios-fg =  <&pio 0  17 GPIO_ACTIVE_HIGH>;
		};

		pwm2 {
			label = "pwm2";
			gpios = <&pio 6 9 GPIO_ACTIVE_HIGH>;
			gpios-fg =  <&pio 0  3 GPIO_ACTIVE_HIGH>;
		};
		
		pwm3{
			label = "pwm3";
			gpios = <&pio 6 11 GPIO_ACTIVE_HIGH>;	
			gpios-fg =  <&pio 0 21 GPIO_ACTIVE_HIGH>;
		};	
		
		pwm4{
			label = "pwm4";
			gpios = <&pio 6 12 GPIO_ACTIVE_HIGH>;	
			gpios-fg =  <&pio 0 20 GPIO_ACTIVE_HIGH>;
		};	
 	};
 

  

(2)编写驱动

  • 解析dts文件,获取fg脚
	for_each_child_of_node(node, fg) 
	{
		enum of_gpio_flags flagsfg;

		if (!of_find_property(fg, "gpios-fg", NULL)) 
		{
			pdata->npwms--;
			printk( "Fail to find gpios-fg\n");
			continue;
		}

		pwm = &pdata->pwms[i++];
		pwm->gpio_fg = of_get_named_gpio_flags(fg,"gpios-fg", 0, &flagsfg);
		printk("pwm->gpio-fg=%d,flags=%d",pwm->gpio_fg,flagsfg);
		if (pwm->gpio_fg < 0)
		{
			error = pwm->gpio_fg;
			if (error != -ENOENT) 
			{
				if (error != -EPROBE_DEFER)
					dev_err(dev,
						"Failed to get gpio-fg flags, error: %d\n",
						error);
				return ERR_PTR(error);
			}
		} 
		
	}

  

  • 申请中断
 switch(gpiofg)
	{
		case 17:
		       error= devm_gpio_request(dev, gpiofg,"fan1_FG");  break;
		case 3:
		      error= devm_gpio_request(dev, gpiofg,"fan2_FG");  break;
		case  21:
		      error= devm_gpio_request(dev, gpiofg,"fan3_FG");  break;
		case 20:
		      error= devm_gpio_request(dev, gpiofg,"fan4_FG");  break;
		default:
			break;
	}
	
	if (error){
		printk( "unable to request gpio %u, err=%d\n",
				gpiofg, error);
		}
	gpwm->irq_fg= gpio_to_irq(gpiofg); //获取一个gpio对应的中断号
	if (gpwm->irq_fg < 0)
	{
	     printk("return irq number error!");
	}
		
	

	switch(gpiofg)
	{
		case 17:
		        pin1FGirq = gpwm->irq_fg;
			INIT_WORK(&gpwm->gpiofg_work, fan1_speed);   //初始化工作队列
			irq_set_irq_type(gpwm->irq_fg, IRQ_TYPE_EDGE_FALLING);	  //设置触发类型
			error = devm_request_irq(&pdev->dev, gpwm->irq_fg, get_fan_speed_irq_handler,
		       IRQF_SHARED,"fan1_FG", gpwm);   //申请中断设置中断类型为 共享中断
				break;
		case 3:
			  pin2FGirq = gpwm->irq_fg;
			  INIT_WORK(&gpwm->gpiofg_work, fan2_speed);
			error = devm_request_irq(&pdev->dev, gpwm->irq_fg, get_fan_speed_irq_handler,
		       IRQF_SHARED,"fan2_FG", gpwm);
			  break;
		case  21:
			  pin3FGirq = gpwm->irq_fg;  
			  INIT_WORK(&gpwm->gpiofg_work, fan3_speed);
			error = devm_request_irq(&pdev->dev, gpwm->irq_fg, get_fan_speed_irq_handler,
		       IRQF_SHARED,"fan3_FG", gpwm);	
			  break;
		case 20:
			  pin4FGirq = gpwm->irq_fg;  
			  INIT_WORK(&gpwm->gpiofg_work, fan4_speed);
			error = devm_request_irq(&pdev->dev, gpwm->irq_fg, get_fan_speed_irq_handler,
		       IRQF_SHARED,"fan4_FG", gpwm);	  
			  break;
		default:
			break;
	}
	
	
	if (error) {
			printk( "failed to  request irq, err=%d\n", error);
		}
	  disable_irq(gpwm->irq_fg);   //默认关闭中断
	}
 
  • 中断服务程序
static irqreturn_t get_fan_speed_irq_handler(int irq, void *dev_id)
{
	struct pwm_chip *gpiofg_data = dev_id;
	schedule_work(&gpiofg_data->gpiofg_work);  //schedule_work(work)来通知内核线程,然后中断结束后,再去继续执行work对应的func函数
	return IRQ_HANDLED;
}
注意:
    //中断服务程序的返回值必须为IRQ_HANDLED
    /**
 * enum irqreturn
 * @IRQ_NONE		interrupt was not from this device or was not handled
 * @IRQ_HANDLED		interrupt was handled by this device
 * @IRQ_WAKE_THREAD	handler requests to wake the handler thread
 */
enum irqreturn {
	IRQ_NONE		= (0 << 0),
	IRQ_HANDLED		= (1 << 0),
	IRQ_WAKE_THREAD		= (1 << 1),
};

  中断服务程序有三个返回值,三个值代表不同意思,如果返回值为IR_NONE,系统会认为这个中断没有被处理(但是中断程序执行了),当 未处理中断次数超过100000次时,系统会disable掉这个中断。系统会认为中断卡死了,这是共享中断的特性,会根据中断服务程序的返回值判断中断程序是否被处理。

     当一个中断号上有多个中断共享的时候,该中断来的时候,内核会依次调用共享该中断号的各个中断处理函数,如果中断处理函数检测到该中断不是自己的中断时就会返回IRQ_NONE,这时内核就会调用下一个中断处理函数,而这些中断处理函数中必须至少有一个返回IRQ_HANDLED告知内核该中断是自己的中断,已经正常处理,若内核依次调用完所有该中断号的中断处理函数仍未得到IRQ_HANDLED的返回值,内核就会报告上述错误,并在该中断出现一定次数后关闭该中断。即只有中断处理函数返回 IRQ_HANDLED ,这个中断才是被正确完成的。

中断卡死的处理过程:

//Linux-4.14.25/kernel/irq/spurious.c

irq = irq_desc_get_irq(desc);
	if (unlikely(try_misrouted_irq(irq, desc, action_ret))) {
		int ok = misrouted_irq(irq);
		if (action_ret == IRQ_NONE)
			desc->irqs_unhandled -= ok;
	}

	desc->irq_count++;
	if (likely(desc->irq_count < 100000))
		return;

	desc->irq_count = 0;
	if (unlikely(desc->irqs_unhandled > 99900)) {
		/*
		 * The interrupt is stuck
		 */
		__report_bad_irq(desc, action_ret);
		/*
		 * Now kill the IRQ
		 */
		printk(KERN_EMERG "Disabling IRQ #%d\n", irq);
		desc->istate |= IRQS_SPURIOUS_DISABLED;
		desc->depth++;
		irq_disable(desc);

		mod_timer(&poll_spurious_irq_timer,
			  jiffies + POLL_SPURIOUS_IRQ_INTERVAL);
	}
	desc->irqs_unhandled = 0;
} 

查看中断信息:

通过风扇FG脚检测风扇转速

通过风扇FG脚检测风扇转速

  • 工作队列的任务
static void fan1_speed(struct work_struct *ws)
{
    	  pinFG1_frequency++;
}
static void fan2_speed(struct work_struct *ws)
{
    	  pinFG2_frequency++;
}
static void fan3_speed(struct work_struct *ws)
{
    	  pinFG3_frequency++;
}
static void fan4_speed(struct work_struct *ws)
{
    	  pinFG4_frequency++;
}

  

工作队列的介绍

在中断处理中,经常用到工作队列,这样便能缩短中断处理时的时间

//工作队列初始化函数

INIT_WORK(work, func);

中断中通过调用schedule_work(work)来通知内核线程,然后中断结束后,再去继续执行work对应的func函数

示例

当中断来了,立马调用schedule_work(work),然后退出.

中断结束后,内核便会调用_work对应的func函数,最后才来读取按键值,上报按键值,这样就大大缩短了中断处理时间

  • 定时器初始化
static void fan1_init_timer(void)

{
	fan1timer.expires = jiffies+100;//设定 超时时间,100代表1秒?
	timer_setup(&fan1timer, fan1_timer, 0);   
	add_timer(&fan1timer); //添加定时器,定时器开始生效
	enable_irq(pin1FGirq);
}

static void fan2_init_timer(void)
{
	fan2timer.expires = jiffies+100;//设定 超时时间,100代表1秒
	timer_setup(&fan2timer, fan2_timer, 0);  //准备timer,并设置超时时执行的函数。
	add_timer(&fan2timer); //添加定时器,定时器开始生效
	enable_irq(pin2FGirq);
}

static void fan3_init_timer(void)
{
	fan3timer.expires = jiffies+100;//设定 超时时间,100代表1秒
	timer_setup(&fan3timer, fan3_timer, 0);
	add_timer(&fan3timer); //添加定时器,定时器开始生效
	enable_irq(pin3FGirq);
}

static void fan4_init_timer(void)
{
	fan4timer.expires = jiffies+100;//设定 超时时间,100代表1秒
	timer_setup(&fan4timer, fan4_timer, 0);
	add_timer(&fan4timer); //添加定时器,定时器开始生效
	enable_irq(pin4FGirq);
}
  • 定时器超时处理函数
static void fan1_timer(struct timer_list *t)
{
	pinFG_frequency[0] = pinFG1_frequency;
	pinFG1_frequency = 0;
	mod_timer(&fan1timer,jiffies+100);  //	修改定时器的expire
}

static void fan2_timer(struct timer_list *t)
{
	pinFG_frequency[1] = pinFG2_frequency;
	pinFG2_frequency = 0;
	mod_timer(&fan2timer,jiffies+100);	
}

static void fan3_timer(struct timer_list *t)
{

	pinFG_frequency[2] = pinFG3_frequency;
	pinFG3_frequency = 0;
	mod_timer(&fan3timer,jiffies+100);	
}

static void fan4_timer(struct timer_list *t)
{
	pinFG_frequency[3] = pinFG4_frequency;
	pinFG4_frequency = 0;
	mod_timer(&fan4timer,jiffies+100);	
}
  • read函数(应用层read会调用到这个函数)
ssize_t pwm_drv_read (struct file *filp, char __user *userbuf, size_t count, loff_t *fpos)
{
	int ret=0, i = 0,j=0;
	unsigned char tmp[8] ={0};
	//应用层从内核读取数据时,只能一个字节一个字节读,所以将频率short型数据要分成两个单字节数据读。
	while(i<8)
	{
		tmp[i] = pinFG_frequency[j]>>8 ;
		tmp[i+1] = pinFG_frequency[j];
		i+=2;
		j++;
	}
      ret= copy_to_user(userbuf, tmp, sizeof(tmp)/sizeof(tmp[0]));
	if(ret==1)
	{
	     printk("copy data error!\n");
		ret = -1;
	}
 	  return ret;

  

(3)应用层获取数据 

void fan_get_rotating_speed(uint16_t *arg,uint8_t len)
{
	
	int fd=-1,ret=-1,i=0,j=0;
	uint8_t recv_buff[8]={0};
	uint16_t pinFG_Freqency[4]={0};
	printf("fan_get_rotating_speed\n");
	
	fd = open(dev_fan[0].description,O_RDWR );	 
	if(fd < 0)
	{			
		printf("failed to open pwm0 failed!\n");
	}
	//读取数据
	ret = read(fd,recv_buff,len*2);	
	if(ret<0)
	{
		printf("get fan rotating speed error!");	
	}
       //将8个字节的数据合成4个short型数据
	 while(i<8)
	{
		pinFG_Freqency[j] = (unsigned short)recv_buff[i]<<8|recv_buff[i+1];
		i+=2;
		j++;
	}
	//计算转速
	 for(i=0;i<len;i++)
	 {
	 	arg[i]=(uint16_t)((60*pinFG_Freqency[i])/2);  
	 }
	close(fd);
}

  

driver-ipollo.c中去调用

 else if (strcasecmp(option, "getallstats") == 0) {  
		char tmp_str[64] = { 0 };
		uint16_t fan_speed[4]={0};
		fan_get_rotating_speed(fan_speed,sizeof(fan_speed)/sizeof(fan_speed[0]));
		sprintf(tmp_str, "\"fanspeed[0:%d]:[1:%d][2:%d][3:%d]\"",fan_speed[0],fan_speed[1],fan_speed[2],fan_speed[3]);
		strcat(replybuf, tmp_str);

可通过命令去获取风速:



echo -n "ascset|0,getallstats" | nc 192.168.1.100 4028 && echo
通过风扇FG脚检测风扇转速

 


 

 
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