Makefile文件分析

# disable/enable debugging

#DEBUG = y

# 当DEBUG变量等于y时。两个比较变量用括号括起来，逗号分隔。ifeq和括号中间有一个空格。

ifeq ($(DEBUG), y)

# += 追加变量值。如果该变量之前没有被定义过，+=就自动变成=，变量被定义成递归展开式的变量；如果之前已经定义过，就遵循之前的风格。

# = 递归展开式变量：在定义时，变量中对其它变量的引用不会被替换展开。变量在引用它的地方被替换展开时，变量中其它变量才被同时替换展开。

# -O 程序优化参数；

# -g 使生成的debuginfo包额外支持gnu和gdb调试程序，易于使用

# -DSCULL_DEBUG 即define SCULL_DEBUG   TODO

    DEBFLAGS += -O -g -DSCULL_DEBUG # -O is needed to expand inlines

else

    DEBFLAGS += -O2

endif

#  CFLAGS影响编译过程。应在遵循原设置的基础上添加新的设置，注意+=

CFLAGS += $(DEBFLAGS)

# -I 选项指出头文件位置。LDDINC是下面定义的一个变量。

CFLAGS += -I$(LDDINC)

# 如果KERNELRELEASE不等于空。ifneq判断参数是否不相等。

ifneq ($(KERNELRELEASE),)

# := 直接展开式变量：在定义时就展开变量中对其它变量或函数的引用，定以后就成了需要定义的文本串。不能实现对其后定义变量的引用。

scull-objs := main.o pipe.o access.o

obj-m := scull.o

# 否则（KERNELRELEASE是空）

else

# ?= 条件赋值：只有在此变量之前没有赋值的情况下才会被赋值。

# shell uname r 内核版本号

KERNELDIR ?= /lib/modules/$(shell uname r)/build

# shell pwd 当前在文件系统中的路径

PWD := $(shell pwd)

modules:

    # $(MAKE) TODO

    # -C $(KERNELDIR) 在读取Makefile之前进入$(KERNELDIR)目录

    # M=$(PWD) LDDINC=$(PWD)/../include 传递2个变量给Makefile

    # modules 是$(KERNELDIR)中的Makefile的target   TODO

    $(MAKE) -C $(KERNELDIR) M=$(PWD) LDDINC=$(PWD)/../include modules

endif

# 清理

clean:

    rm -rf *.o *~ core .depend .*.cmd *.ko *.mod.c .tmp_versions

# TODO

# 产生依赖信息文件，如果存在的话则将其包含到Makefile中。

depend .depend dep:

    $(CC) $(CFLAGS) -M *.c > .depend

ifeq (.depend,$(wildcard .depend))

include .depend

endif

---

参考

.[GNU make中文手册]

.[CFLAGS 统一和 gcc 3.4] http://www.magiclinux.org/node/821

.[LDD3源码学习笔记之scull_main] http://www.sudu.cn/info/html/edu/20070101/291462.html

.http://topic.****.net/u/20070815/22/cbd2f64d-f6e3-4938-97f8-4f8fe5a21465.html

 scull.h

/*

 * scull.h -- definitions for the char module

 *

 * Copyright (C) 2001 Alessandro Rubini and Jonathan Corbet

 * Copyright (C) 2001 O'Reilly & Associates

 *

 * The source code in this file can be freely used, adapted,

 * and redistributed in source or binary form, so long as an

 * acknowledgment appears in derived source files.  The citation

 * should list that the code comes from the book "Linux Device

 * Drivers" by Alessandro Rubini and Jonathan Corbet, published

 * by O'Reilly & Associates.   No warranty is attached;

 * we cannot take responsibility for errors or fitness for use.

 *

 * $Id: scull.h,v 1.15 2004/11/04 17:51:18 rubini Exp $

 */

#ifndef _SCULL_H_

#define _SCULL_H_

#include <linux/ioctl.h> /* needed for the _IOW etc stuff used later */

/*

 * Macros to help debugging

 */

// undef取消以前定义的宏

#undef PDEBUG             /* undef it, just in case */

#ifdef SCULL_DEBUG

#  ifdef __KERNEL__

     // 内核空间，printk 输出调试信息

     /* This one if debugging is on, and kernel space */

#    define PDEBUG(fmt, args) printk( KERN_DEBUG "scull: " fmt, ## args)

#  else

     // 用户空间，fprintf 输出调试信息

     /* This one for user space */

#    define PDEBUG(fmt, args) fprintf(stderr, fmt, ## args)

#  endif

#else

#  define PDEBUG(fmt, args) /* not debugging: nothing */

#endif

#undef PDEBUGG

#define PDEBUGG(fmt, args) /* nothing: it's a placeholder */

#ifndef SCULL_MAJOR

// 主设备号指定为0，表示由内核动态分配

#define SCULL_MAJOR 0   /* dynamic major by default */

#endif

// bare device的数量，也就是要请求的连续设备编号的总数

#ifndef SCULL_NR_DEVS

#define SCULL_NR_DEVS 4    /* scull0 through scull3 */

#endif

// TODO

#ifndef SCULL_P_NR_DEVS

#define SCULL_P_NR_DEVS 4  /* scullpipe0 through scullpipe3 */

#endif

/*

 * The bare device is a variable-length region of memory.

 * Use a linked list of indirect blocks.

 *

 * "scull_dev->data" points to an array of pointers, each

 * pointer refers to a memory area of SCULL_QUANTUM bytes.

 *

 * The array (quantum-set) is SCULL_QSET long.

 */

 // 每个内存区字节数。（量子长度）

#ifndef SCULL_QUANTUM

#define SCULL_QUANTUM 4000

#endif

// 数组长度（量子集长度）

#ifndef SCULL_QSET

#define SCULL_QSET    1000

#endif

/*

 * The pipe device is a simple circular buffer. Here its default size

 */

// 管道设备，环形缓冲大小。

#ifndef SCULL_P_BUFFER

#define SCULL_P_BUFFER 4000

#endif

/*

 * Representation of scull quantum sets.

 */

struct scull_qset {

    void **data;

    struct scull_qset *next;

};

// 使用scull_dev表示每个设备

struct scull_dev {

    struct scull_qset *data;  /* Pointer to first quantum set */

    int quantum;              /* the current quantum size */

    int qset;                 /* the current array size */

    unsigned long size;       /* amount of data stored here */

    unsigned int access_key;  /* used by sculluid and scullpriv */

    struct semaphore sem;     /* mutual exclusion semaphore     */

    struct cdev cdev;      /* Char device structure        */

};

// TODO 什么用？

/*

 * Split minors in two parts

 */

// 高四位

#define TYPE(minor)    (((minor) >> 4) & 0xf)    /* high nibble */

// 低四位

#define NUM(minor)    ((minor) & 0xf)        /* low  nibble */

/*

 * The different configurable parameters

 */

extern int scull_major;     /* main.c */

extern int scull_nr_devs;

extern int scull_quantum;

extern int scull_qset;

extern int scull_p_buffer;    /* pipe.c */

/*

 * Prototypes for shared functions

 */

int     scull_p_init(dev_t dev);

void    scull_p_cleanup(void);

int     scull_access_init(dev_t dev);

void    scull_access_cleanup(void);

int     scull_trim(struct scull_dev *dev);

ssize_t scull_read(struct file *filp, char __user *buf, size_t count,

                   loff_t *f_pos);

ssize_t scull_write(struct file *filp, const char __user *buf, size_t count,

                    loff_t *f_pos);

loff_t  scull_llseek(struct file *filp, loff_t off, int whence);

int     scull_ioctl(struct inode *inode, struct file *filp,

                    unsigned int cmd, unsigned long arg);

/*

 * Ioctl definitions

 */

// TODO 魔数什么用？

/* Use 'k' as magic number */

#define SCULL_IOC_MAGIC  'k'

/* Please use a different 8-bit number in your code */

#define SCULL_IOCRESET    _IO(SCULL_IOC_MAGIC, 0)

/*

 * S means "Set" through a ptr,

 * T means "Tell" directly with the argument value

 * G means "Get": reply by setting through a pointer

 * Q means "Query": response is on the return value

 * X means "eXchange": switch G and S atomically

 * H means "sHift": switch T and Q atomically

 */

#define SCULL_IOCSQUANTUM _IOW(SCULL_IOC_MAGIC,  1, int)

#define SCULL_IOCSQSET    _IOW(SCULL_IOC_MAGIC,  2, int)

#define SCULL_IOCTQUANTUM _IO(SCULL_IOC_MAGIC,   3)

#define SCULL_IOCTQSET    _IO(SCULL_IOC_MAGIC,   4)

#define SCULL_IOCGQUANTUM _IOR(SCULL_IOC_MAGIC,  5, int)

#define SCULL_IOCGQSET    _IOR(SCULL_IOC_MAGIC,  6, int)

#define SCULL_IOCQQUANTUM _IO(SCULL_IOC_MAGIC,   7)

#define SCULL_IOCQQSET    _IO(SCULL_IOC_MAGIC,   8)

#define SCULL_IOCXQUANTUM _IOWR(SCULL_IOC_MAGIC, 9, int)

#define SCULL_IOCXQSET    _IOWR(SCULL_IOC_MAGIC,10, int)

#define SCULL_IOCHQUANTUM _IO(SCULL_IOC_MAGIC,  11)

#define SCULL_IOCHQSET    _IO(SCULL_IOC_MAGIC,  12)

/*

 * The other entities only have "Tell" and "Query", because they're

 * not printed in the book, and there's no need to have all six.

 * (The previous stuff was only there to show different ways to do it.

 */

#define SCULL_P_IOCTSIZE _IO(SCULL_IOC_MAGIC,   13)

#define SCULL_P_IOCQSIZE _IO(SCULL_IOC_MAGIC,   14)

/*  more to come */

#define SCULL_IOC_MAXNR 14

#endif /* _SCULL_H_ */

main.c

/*

 * main.c -- the bare scull char module

 *

 * Copyright (C) 2001 Alessandro Rubini and Jonathan Corbet

 * Copyright (C) 2001 O'Reilly & Associates

 *

 * The source code in this file can be freely used, adapted,

 * and redistributed in source or binary form, so long as an

 * acknowledgment appears in derived source files.  The citation

 * should list that the code comes from the book "Linux Device

 * Drivers" by Alessandro Rubini and Jonathan Corbet, published

 * by O'Reilly & Associates.   No warranty is attached;

 * we cannot take responsibility for errors or fitness for use.

 *

 */

#include <linux/config.h>

#include <linux/module.h>

#include <linux/moduleparam.h>

#include <linux/init.h>

#include <linux/kernel.h>    /* printk() */

#include <linux/slab.h>        /* kmalloc() */

#include <linux/fs.h>        /* everything */

#include <linux/errno.h>    /* error codes */

#include <linux/types.h>    /* size_t */

#include <linux/proc_fs.h>

#include <linux/fcntl.h>    /* O_ACCMODE */

#include <linux/seq_file.h>

#include <linux/cdev.h>

#include <asm/system.h>        /* cli(), *_flags */

#include <asm/uaccess.h>    /* copy_*_user */

#include "scull.h"        /* local definitions */

/*

 * Our parameters which can be set at load time.

 */

int scull_major =   SCULL_MAJOR; // 主设备号

int scull_minor =   ; // 次设备号

int scull_nr_devs = SCULL_NR_DEVS;    /* number of bare scull devices */

int scull_quantum = SCULL_QUANTUM;  // 量子大小（字节）

int scull_qset =    SCULL_QSET; // 量子集大小

// 插入模块时指定的参数

module_param(scull_major, int, S_IRUGO);

module_param(scull_minor, int, S_IRUGO);

module_param(scull_nr_devs, int, S_IRUGO);

module_param(scull_quantum, int, S_IRUGO);

module_param(scull_qset, int, S_IRUGO);

MODULE_AUTHOR("Alessandro Rubini, Jonathan Corbet");

MODULE_LICENSE("Dual BSD/GPL");

struct scull_dev *scull_devices;    /* allocated in scull_init_module */

// 释放整个数据区。简单遍历列表并且释放它发现的任何量子和量子集。

// 在scull_open 在文件为写而打开时调用。

// 调用这个函数时必须持有信号量。

/*

 * Empty out the scull device; must be called with the device

 * semaphore held.

 */

int scull_trim(struct scull_dev *dev)

{

    struct scull_qset *next, *dptr;

    int qset = dev->qset;   /* "dev" is not-null */ // 量子集大小

    int i;

    // 遍历多个量子集。dev->data 指向第一个量子集。

    for (dptr = dev->data; dptr; dptr = next) { /* all the list items */

        if (dptr->data) { // 量子集中有数据

            for (i = ; i < qset; i++) // 遍历释放当前量子集中的每个量子。量子集大小为qset。

                kfree(dptr->data[i]);

            kfree(dptr->data); // 释放量子指针数组

            dptr->data = NULL;

        }

        // next获取下一个量子集，释放当前量子集。

        next = dptr->next;

        kfree(dptr);

    }

    // 清理struct scull_dev dev中变量的值

    dev->size = ;

    dev->quantum = scull_quantum;

    dev->qset = scull_qset;

    dev->data = NULL;

    return ;

}

#ifdef SCULL_DEBUG /* use proc only if debugging */

/*

 * The proc filesystem: function to read and entry

 */

 // 在proc里实现文件，在文件被读时产生数据

 // 当一个进程读 /proc 文件，内核分配了一页内存，驱动可以写入数据返回用户空间

int scull_read_procmem(char *buf,  // 写数据的缓冲区

                char **start,  // 数据写在页中的哪里

                off_t offset,

                int count,

                int *eof,  // 必须被驱动设置，表示写数据结束

                void *data) // data传递私有数据

{

    int i, j, len = ;

    int limit = count - ; /* Don't print more than this */

    // 遍历每个设备，输出总字节数小于limit

    for (i = ; i < scull_nr_devs && len <= limit; i++) {

        struct scull_dev *d = &scull_devices[i];

        struct scull_qset *qs = d->data;

        if (down_interruptible(&d->sem))

            return -ERESTARTSYS;

        len += sprintf(buf+len,"\nDevice %i: qset %i, q %i, sz %li\n",  // 输出当前是第几个scull设备，量子集大小，量子大小，设备大小

                i, d->qset, d->quantum, d->size);

        // 遍历当前设备的每个量子集

        for (; qs && len <= limit; qs = qs->next) { /* scan the list */

            len += sprintf(buf + len, "  item at %p, qset at %p\n",     // 输出当前量子集 和 量子集中的数据 在内存中的位置。

                    qs, qs->data);

            // 输出最后一个量子集中，每个量子的地址

            if (qs->data && !qs->next) /* dump only the last item */

                for (j = ; j < d->qset; j++) {

                    if (qs->data[j])

                        len += sprintf(buf + len,

                                "    % 4i: %8p\n",

                                j, qs->data[j]);

                }

        }

        up(&scull_devices[i].sem);

    }

    *eof = ;

    return len;

}

/// seq_file接口：创建一个虚拟文件，遍历一串数据，这些数据必须返回用户空间。

// 步骤：start, next, stop, show

/*

 * For now, the seq_file implementation will exist in parallel.  The

 * older read_procmem function should maybe go away, though.

 */

/*

 * Here are our sequence iteration methods.  Our "position" is

 * simply the device number.

 */

// 参数：*s总被忽略；pos指从哪儿开始读，具体意义依赖于实现。

// seq_file典型的实现是遍历一感兴趣的数据序列，pos就用来指示序列中的下一个元素。

// 在scull中，pos简单地作为scull_array数组的索引。

static void *scull_seq_start(struct seq_file *s, loff_t *pos)

{

    if (*pos >= scull_nr_devs)

        return NULL;   /* No more to read */

    return scull_devices + *pos; // 返回索引号是pos的scull设备

}

// 返回下一个scull设备

static void *scull_seq_next(struct seq_file *s, void *v, loff_t *pos)

{

    (*pos)++;

    if (*pos >= scull_nr_devs)

        return NULL;

    return scull_devices + *pos;

}

static void scull_seq_stop(struct seq_file *s, void *v)

{

    /* Actually, there's nothing to do here */

}

// 输出迭代器v生成的数据到用户空间

static int scull_seq_show(struct seq_file *s, void *v)

{

    struct scull_dev *dev = (struct scull_dev *) v;

    struct scull_qset *d;

    int i;

    if (down_interruptible(&dev->sem))

        return -ERESTARTSYS;

    seq_printf(s, "\nDevice %i: qset %i, q %i, sz %li\n", // 输出，相当于用于空间的printf。返回非0值表示缓冲区满，超出的数据被丢弃。

            (int) (dev - scull_devices), dev->qset,

            dev->quantum, dev->size);

     // 遍历设备的每一个量子集

    for (d = dev->data; d; d = d->next) { /* scan the list */

        seq_printf(s, "  item at %p, qset at %p\n", d, d->data); // 量子集地址，量子集中数据地址

        // 输出最后一个量子集中，每个量子的地址

        if (d->data && !d->next) /* dump only the last item */

            for (i = ; i < dev->qset; i++) {

                if (d->data[i])

                    seq_printf(s, "    % 4i: %8p\n",

                            i, d->data[i]);

            }

    }

    up(&dev->sem);

    return ;

}

// seq_file的操作集

/*

 * Tie the sequence operators up.

 */

static struct seq_operations scull_seq_ops = {

    .start = scull_seq_start,

    .next  = scull_seq_next,

    .stop  = scull_seq_stop,

    .show  = scull_seq_show

};

// 打开 /proc 文件。在这里也就是初始化seq_file

/*

 * Now to implement the /proc file we need only make an open

 * method which sets up the sequence operators.

 */

static int scull_proc_open(struct inode *inode, struct file *file)

{

    return seq_open(file, &scull_seq_ops); // 连接file和seq_file

}

// proc文件的操作集

/*

 * Create a set of file operations for our proc file.

 */

static struct file_operations scull_proc_ops = {

    .owner   = THIS_MODULE,

    .open    = scull_proc_open,

    .read    = seq_read,

    .llseek  = seq_lseek,

    .release = seq_release

};

/*

 * Actually create (and remove) the /proc file(s).

 */

// 建立通过proc方式debug时需要的proc文件

static void scull_create_proc(void)

{

    struct proc_dir_entry *entry;

    //TODO 创建了两个文件?

    // 创建文件scullmem并使之关联read函数

    create_proc_read_entry("scullmem",   // name:要创建的文件名

             /* default mode */,   // mode:文件掩码，为0则按照系统默认的掩码创建文件

            NULL /* parent dir */,  // base:指定文件所在目录，为NULL则被创建在/proc根目录下

            scull_read_procmem,  // read_proc:处理读请求的回调函数

            NULL /* client data */); // 内核忽略此参数，但会把它当做参数传递给read_proc

    entry = create_proc_entry("scullseq", , NULL); // 参数:名字，掩码，父目录

                                                   // create_proc_entry 同样用来建立/proc文件，但较create_proc_read_entry 更为底层一些

    if (entry)

        entry->proc_fops = &scull_proc_ops;

}

// 移除创建的 /proc 文件

static void scull_remove_proc(void)

{

    /* no problem if it was not registered */

    // 移除一个proc_dir_entry, 如果这个结构还在使用，设置deleted标志，返回

    remove_proc_entry("scullmem",   // const char *name

                    NULL /* parent dir */);    // struct proc_dir_entry *parent

    remove_proc_entry("scullseq", NULL);

}

#endif /* SCULL_DEBUG */

/*

 * Open and close

 */

/// 打开设备:文件私有数据，设置成对应的scull_dev

int scull_open(struct inode *inode, struct file *filp)

{

    struct scull_dev *dev; /* device information */

    dev = container_of(inode->i_cdev, struct scull_dev, cdev);

    filp->private_data = dev; /* for other methods */

    /* now trim to 0 the length of the device if open was write-only */

    /// 文件以只读模式打开时，截断为0

    if ( (filp->f_flags & O_ACCMODE) == O_WRONLY) {

        if (down_interruptible(&dev->sem))

            return -ERESTARTSYS;

        scull_trim(dev); /* ignore errors */

        up(&dev->sem);

    }

    return ;          /* success */

}

// file_operations 中的.release

int scull_release(struct inode *inode, struct file *filp)

{

    return ;

}

/*

 * Follow the list

 */

 // 返回设备dev的第n个量子集，量子集不够n个就申请新的。

struct scull_qset *scull_follow(struct scull_dev *dev, int n)

{

    struct scull_qset *qs = dev->data; // 当前设备的量子集

        /* Allocate first qset explicitly if need be */

    // 如果当前设备还没有量子集，就显式分配第一个量子集

    if (! qs) {

                             // kmalloc 内核模块中，动态分配连续的物理地址，用于小内存分配

        qs = dev->data = kmalloc(sizeof(struct scull_qset), // size_t size. 要分配的块的大小

                                GFP_KERNEL);    // int flags. GFP_KERNEL 在当前进程缺少内存时，可以睡眠来等待一页。 TODO

                                                // 使用 GFP_KERNEL 来分配内存的函数，必须可重入 且不能在原子上下文中运行。

        if (qs == NULL)

            return NULL;  /* Never mind */

        memset(qs, , sizeof(struct scull_qset));

    }

    /* Then follow the list */

    // 遍历当前设备的量子集链表n步，量子集不够就申请新的。

    while (n--) {

        if (!qs->next) {

            qs->next = kmalloc(sizeof(struct scull_qset), GFP_KERNEL);

            if (qs->next == NULL) // 不关心内存分配失败? TODO

                return NULL;  /* Never mind */

            memset(qs->next, , sizeof(struct scull_qset));

        }

        qs = qs->next;

        continue;

    }

    return qs;

}

/*

 * Data management: read and write

 */

ssize_t scull_read(struct file *filp,   // 设备对应的文件结构

                    char __user *buf,    // 读到用户空间

                    size_t count,       // 字节数

                loff_t *f_pos)          // 要读的位置，在filp私有数据中的偏移

{

    struct scull_dev *dev = filp->private_data;

    struct scull_qset *dptr;    /* the first listitem */

    int quantum = dev->quantum, qset = dev->qset; // 量子、量子集大小

    int itemsize = quantum * qset; /* how many bytes in the listitem */ // 一个量子集的字节数

    int item, s_pos, q_pos, rest;

    ssize_t retval = ;

    if (down_interruptible(&dev->sem))

        return -ERESTARTSYS;

    if (*f_pos >= dev->size)

        goto out;

    // 要读的count超出了size，裁断count

    if (*f_pos + count > dev->size)

        count = dev->size - *f_pos;

    /* find listitem, qset index, and offset in the quantum */

    // 在量子/量子集中定位读写位置:第几个量子集，中的 第几个量子，在量子中的偏移

    item = (long)*f_pos / itemsize; // 第几个量子集

    rest = (long)*f_pos % itemsize; // 在量子集中的偏移量

    s_pos = rest / quantum; q_pos = rest % quantum; // 第几个量子；在量子中的偏移

    /* follow the list up to the right position (defined elsewhere) */

    // 获取要读的量子集指针

    dptr = scull_follow(dev, item);

    if (dptr == NULL || !dptr->data || ! dptr->data[s_pos]) // 没有量子集，量子集中没有data，没有第s_pos个量子

        goto out; /* don't fill holes */

    /* read only up to the end of this quantum */

    // 只在一个量子中读:如果count超出当前量子，截断count

    if (count > quantum - q_pos)

        count = quantum - q_pos;

    // 将读位置的内容复制到用户空间buf，共复制count字节

    if (copy_to_user(buf,       // void __user *to

                    dptr->data[s_pos] + q_pos,  // const void *from

                    count)) {   // unsigned long n

        retval = -EFAULT;

        goto out;

    }

    *f_pos += count;

    retval = count;

  out:

    up(&dev->sem);

    return retval;

}

ssize_t scull_write(struct file *filp,  // 设备对应的文件结构

                    const char __user *buf,

                    size_t count,

                loff_t *f_pos)

{

    struct scull_dev *dev = filp->private_data;

    struct scull_qset *dptr;

    int quantum = dev->quantum, qset = dev->qset; // 量子、量子集大小

    int itemsize = quantum * qset;      // 一个量子集的字节数

    int item, s_pos, q_pos, rest;

    ssize_t retval = -ENOMEM; /* value used in "goto out" statements */

    if (down_interruptible(&dev->sem))

        return -ERESTARTSYS;

    /* find listitem, qset index and offset in the quantum */

    // 查找量子集，在量子集中的索引，和在量子中的偏移

    item = (long)*f_pos / itemsize;

    rest = (long)*f_pos % itemsize;

    s_pos = rest / quantum; q_pos = rest % quantum;

    // 获取要写入数据的量子集

    /* follow the list up to the right position */

    dptr = scull_follow(dev, item);     // 获取设备dev的第item个量子集

    if (dptr == NULL)

        goto out;

    // 如果该量子集数据是NULL，就申请一块新内存

    if (!dptr->data) {

        dptr->data = kmalloc(qset * sizeof(char *), GFP_KERNEL);

        if (!dptr->data)

            goto out;

        memset(dptr->data, , qset * sizeof(char *));

    }

    // 如果第s_pos个量子是NULL，申请一块新内存

    if (!dptr->data[s_pos]) {

        dptr->data[s_pos] = kmalloc(quantum, GFP_KERNEL);

        if (!dptr->data[s_pos])

            goto out;

    }

    /* write only up to the end of this quantum */

    if (count > quantum - q_pos)

        count = quantum - q_pos;

    if (copy_from_user(dptr->data[s_pos]+q_pos, buf, count)) { // 从用户空间拷贝数据到内核空间，失败返回没有拷贝的字节数，成功返回0

        retval = -EFAULT;

        goto out;

    }

    *f_pos += count;

    retval = count;

        /* update the size */

    if (dev->size < *f_pos)

        dev->size = *f_pos;

  out:

    up(&dev->sem);

    return retval;

}

/*

 * The ioctl() implementation

 */

int scull_ioctl(struct inode *inode,

                struct file *filp,      // 设备文件

                unsigned int cmd,       // 功能号

                unsigned long arg)      // 参数: 值，或者用户空间指针

{

    int err = , tmp;

    int retval = ;

    /*

     * extract the type and number bitfields, and don't decode

     * wrong cmds: return ENOTTY (inappropriate ioctl) before access_ok()

     */

    // 对错误的命令，返回ENOTTY    TODO

    if (_IOC_TYPE(cmd) != SCULL_IOC_MAGIC) return -ENOTTY;   // 提取ioctl的类型和功能号，不解码

    if (_IOC_NR(cmd) > SCULL_IOC_MAXNR) return -ENOTTY;

    /*

     * the direction is a bitmask, and VERIFY_WRITE catches R/W

     * transfers. `Type' is user-oriented, while

     * access_ok is kernel-oriented, so the concept of "read" and

     * "write" is reversed

     */

    // 如果该ioctl为了读数据，检查当前进程是否可写arg(写到用户空间，用户就读到数据了);如果为了写数据，检查arg是否可读

    if (_IOC_DIR(cmd) & _IOC_READ)  // _IOC_DIR 获取读写属性域值

        // access_ok() 如果当前进程被允许访问用户空间addr处的内存，返回1，否则返回0

        err = !access_ok(VERIFY_WRITE,  // type: Type of access: %VERIFY_READ or %VERIFY_WRITE.

                        (void __user *)arg,  // addr: User space pointer to start of block to check

                        _IOC_SIZE(cmd));     // size: Size of block to check. _IOC_SIZE() 读取数据大小域值

    else if (_IOC_DIR(cmd) & _IOC_WRITE)

        err =  !access_ok(VERIFY_READ, (void __user *)arg, _IOC_SIZE(cmd));

    if (err) return -EFAULT;

    switch(cmd) {

      // 重置量子集、量子大小 TODO:相关内存不同时整理?

      case SCULL_IOCRESET:

        scull_quantum = SCULL_QUANTUM;

        scull_qset = SCULL_QSET;

        break;

      // 设置量子大小,arg是指向量子大小值的指针

      case SCULL_IOCSQUANTUM: /* Set: arg points to the value */

        if (! capable (CAP_SYS_ADMIN)) // 检查是否包含系统管理权限

            return -EPERM;

        // 取arg所指内容，赋值给scull_quantum

        // __get_user() 从用户空间获取一个简单变量，基本不做检查

        retval = __get_user(scull_quantum, // x: variable to store result.

                            (int __user *)arg); // ptr: source address, in user space

        break;

      // 设置量子大小, arg是值

      case SCULL_IOCTQUANTUM: /* Tell: arg is the value */

        if (! capable (CAP_SYS_ADMIN))

            return -EPERM;

        scull_quantum = arg;

        break;

      // 获取量子大小，arg是指针

      case SCULL_IOCGQUANTUM: /* Get: arg is pointer to result */

        retval = __put_user(scull_quantum, (int __user *)arg);

        break;

      // 查询量子大小，返回值 TODO 怎么赋值

      case SCULL_IOCQQUANTUM: /* Query: return it (it's positive) */

        return scull_quantum;

      // 交换量子大小，指针:按arg指向值设置量子大小，当前量子大小保存到arg指向空间

      case SCULL_IOCXQUANTUM: /* eXchange: use arg as pointer */

        if (! capable (CAP_SYS_ADMIN))

            return -EPERM;

        tmp = scull_quantum;

        retval = __get_user(scull_quantum, (int __user *)arg);

        if (retval == )

            retval = __put_user(tmp, (int __user *)arg);

        break;

      // 交换两字大小，值

      case SCULL_IOCHQUANTUM: /* sHift: like Tell + Query */

        if (! capable (CAP_SYS_ADMIN))

            return -EPERM;

        tmp = scull_quantum;

        scull_quantum = arg;

        return tmp;

      // 量子集大小，和上面量子功能类似

      case SCULL_IOCSQSET:  // set

        if (! capable (CAP_SYS_ADMIN))

            return -EPERM;

        retval = __get_user(scull_qset, (int __user *)arg);

        break;

      case SCULL_IOCTQSET: // tell

        if (! capable (CAP_SYS_ADMIN))

            return -EPERM;

        scull_qset = arg;

        break;

      case SCULL_IOCGQSET: // get

        retval = __put_user(scull_qset, (int __user *)arg);

        break;

      case SCULL_IOCQQSET: // query

        return scull_qset;

      case SCULL_IOCXQSET: // eXchange

        if (! capable (CAP_SYS_ADMIN))

            return -EPERM;

        tmp = scull_qset;

        retval = __get_user(scull_qset, (int __user *)arg);

        if (retval == )

            retval = put_user(tmp, (int __user *)arg);

        break;

      case SCULL_IOCHQSET: // sHift

        if (! capable (CAP_SYS_ADMIN))

            return -EPERM;

        tmp = scull_qset;

        scull_qset = arg;

        return tmp;

        /*

         * The following two change the buffer size for scullpipe.

         * The scullpipe device uses this same ioctl method, just to

         * write less code. Actually, it's the same driver, isn't it?

         */

      // tell & query 管道设备缓存大小

      case SCULL_P_IOCTSIZE:

        scull_p_buffer = arg;

        break;

      case SCULL_P_IOCQSIZE:

        return scull_p_buffer;

      default:  /* redundant, as cmd was checked against MAXNR */

        return -ENOTTY;

    }

    return retval;

}

/*

 * The "extended" operations -- only seek

 */

loff_t scull_llseek(struct file *filp,  // 设备文件

                    loff_t off,         // 偏移

                    int whence)         // seek方式

{

    struct scull_dev *dev = filp->private_data;

    loff_t newpos;

    switch(whence) {

      case : /* SEEK_SET */

        newpos = off;

        break;

      case : /* SEEK_CUR */

        newpos = filp->f_pos + off;

        break;

      case : /* SEEK_END */

        newpos = dev->size + off;

        break;

      default: /* can't happen */

        return -EINVAL;

    }

    if (newpos < ) return -EINVAL;

    filp->f_pos = newpos;

    return newpos;

}

struct file_operations scull_fops = {

    .owner =    THIS_MODULE,

    .llseek =   scull_llseek,

    .read =     scull_read,

    .write =    scull_write,

    .ioctl =    scull_ioctl,

    .open =     scull_open,

    .release =  scull_release,

};

/*

 * Finally, the module stuff

 */

/*

 * The cleanup function is used to handle initialization failures as well.

 * Thefore, it must be careful to work correctly even if some of the items

 * have not been initialized

 */

void scull_cleanup_module(void)

{

    int i;

    dev_t devno = MKDEV(scull_major, scull_minor); // MKDEV 把主次设备号合成为一个dev_t结构

    /* Get rid of our char dev entries */

    // 清除字符设备入口

    if (scull_devices) {

        // 遍历释放每个设备的数据区

        for (i = ; i < scull_nr_devs; i++) {

            scull_trim(scull_devices + i);  // 释放数据区

            cdev_del(&scull_devices[i].cdev); // 移除cdev

        }

        kfree(scull_devices);  // 释放scull_devices本身

    }

// 如果使用了/proc来debug，移除创建的/proc文件

#ifdef SCULL_DEBUG /* use proc only if debugging */

    scull_remove_proc();

#endif

    /* cleanup_module is never called if registering failed */

    // 解注册scull_nr_devs个设备号，从devno开始

    unregister_chrdev_region(devno,         // dev_t from

                             scull_nr_devs); // unsigned count

    /* and call the cleanup functions for friend devices */

    scull_p_cleanup();

    scull_access_cleanup();

}

/*

 * Set up the char_dev structure for this device.

 */

 // 建立 char_dev 结构

static void scull_setup_cdev(struct scull_dev *dev, int index)

{

    int err, devno = MKDEV(scull_major, scull_minor + index);

    cdev_init(&dev->cdev, &scull_fops);

    dev->cdev.owner = THIS_MODULE;

    dev->cdev.ops = &scull_fops;

    // 添加字符设备dev->cdev，立即生效

    err = cdev_add (&dev->cdev,     // struct cdev *p: the cdev structure for the device

                    devno,          // dev_t dev: 第一个设备号

                    );             // unsigned count: 该设备连续次设备号的数目

    /* Fail gracefully if need be */

    if (err)

        printk(KERN_NOTICE "Error %d adding scull%d", err, index);

}

int scull_init_module(void)

{

    int result, i;

    dev_t dev = ;

/*

 * Get a range of minor numbers to work with, asking for a dynamic

 * major unless directed otherwise at load time.

 */

    // 申请设备号:获取一系列次设备号, 如果在加载时没有指定主设备号就动态申请一个

    if (scull_major) {

        dev = MKDEV(scull_major, scull_minor);

        // register_chrdev_region 用于已知起始设备的设备号的情况

        result = register_chrdev_region(dev, scull_nr_devs, "scull");

    } else {

        // alloc_chrdev_region 用于设备号未知，向系统动态申请未被占用的设备号情况

        result = alloc_chrdev_region(&dev, scull_minor, scull_nr_devs,

                "scull");

        scull_major = MAJOR(dev);

    }

    if (result < ) {

        printk(KERN_WARNING "scull: can't get major %d\n", scull_major);

        return result;

    }

        /*

     * allocate the devices -- we can't have them static, as the number

     * can be specified at load time

     */

    // 给scull_dev对象申请内存

    scull_devices = kmalloc(scull_nr_devs * sizeof(struct scull_dev), GFP_KERNEL);

    if (!scull_devices) {

        result = -ENOMEM;

        goto fail;  /* Make this more graceful */

    }

    memset(scull_devices, , scull_nr_devs * sizeof(struct scull_dev));

    // 初始化 scull_dev

        /* Initialize each device. */

    for (i = ; i < scull_nr_devs; i++) {

        scull_devices[i].quantum = scull_quantum;

        scull_devices[i].qset = scull_qset;

        init_MUTEX(&scull_devices[i].sem); // 初始化互斥锁，把信号量sem置为1

        scull_setup_cdev(&scull_devices[i], i); // 建立char_dev结构

    }

        /* At this point call the init function for any friend device */

    // TODO

    dev = MKDEV(scull_major, scull_minor + scull_nr_devs);

    dev += scull_p_init(dev);

    dev += scull_access_init(dev);

#ifdef SCULL_DEBUG /* only when debugging */

    scull_create_proc();

#endif

    return ; /* succeed */

  fail:

    scull_cleanup_module();

    return result;

}

module_init(scull_init_module);

module_exit(scull_cleanup_module);

access.c

/*

 * access.c -- the files with access control on open

 *

 * Copyright (C) 2001 Alessandro Rubini and Jonathan Corbet

 * Copyright (C) 2001 O'Reilly & Associates

 *

 * The source code in this file can be freely used, adapted,

 * and redistributed in source or binary form, so long as an

 * acknowledgment appears in derived source files.  The citation

 * should list that the code comes from the book "Linux Device

 * Drivers" by Alessandro Rubini and Jonathan Corbet, published

 * by O'Reilly & Associates.   No warranty is attached;

 * we cannot take responsibility for errors or fitness for use.

 *

 * $Id: access.c,v 1.17 2004/09/26 07:29:56 gregkh Exp $

 */

/* FIXME: cloned devices as a use for kobjects? */

#include <linux/kernel.h> /* printk() */

#include <linux/module.h>

#include <linux/slab.h>   /* kmalloc() */

#include <linux/fs.h>     /* everything */

#include <linux/errno.h>  /* error codes */

#include <linux/types.h>  /* size_t */

#include <linux/fcntl.h>

#include <linux/cdev.h>

#include <linux/tty.h>

#include <asm/atomic.h>

#include <linux/list.h>

#include "scull.h"        /* local definitions */

static dev_t scull_a_firstdev;  /* Where our range begins */

/*

 * These devices fall back on the main scull operations. They only

 * differ in the implementation of open() and close()

 */

// 这些设备主要的scull操作是相同的，仅读写实现不同?

/************************************************************************

 *

 * The first device is the single-open one,

 *  it has an hw structure and an open count

 */

// 第一个设备，只能打开一次。有一个hw结构，和打开计数。 TODO: hw结构是什么?

static struct scull_dev scull_s_device;

// 原子类型，用于计数。初始化原子值为1.

static atomic_t scull_s_available = ATOMIC_INIT(); 

static int scull_s_open(struct inode *inode, struct file *filp)

{

    struct scull_dev *dev = &scull_s_device; /* device information */

    // 如果scull_s_available计数减1不等于0，计数加1，返回-EBUSY

     if (! atomic_dec_and_test (&scull_s_available)) { // 递减原子值；检查是0返回true，否则false

         atomic_inc(&scull_s_available);

        return -EBUSY; /* already open */

    }

    // 否则打开设备

    /* then, everything else is copied from the bare scull device */

    if ( (filp->f_flags & O_ACCMODE) == O_WRONLY)

        scull_trim(dev);

    filp->private_data = dev;

    return ;          /* success */

}

static int scull_s_release(struct inode *inode, struct file *filp)

{

    // scull_s_available加1，恢复1了

    atomic_inc(&scull_s_available); /* release the device */

    return ;

}

/*

 * The other operations for the single-open device come from the bare device

 */

struct file_operations scull_sngl_fops = {

    .owner =    THIS_MODULE,

    .llseek =         scull_llseek,

    .read =           scull_read,

    .write =          scull_write,

    .ioctl =          scull_ioctl,

    .open =           scull_s_open,

    .release =        scull_s_release,

};

/************************************************************************

 *

 * Next, the "uid" device. It can be opened multiple times by the

 * same user, but access is denied to other users if the device is open

 */

// "uid"设备。可以被同一用户多次打开。拒绝其他用户同时打开。

static struct scull_dev scull_u_device;

static int scull_u_count;    /* initialized to 0 by default */

static uid_t scull_u_owner;    /* initialized to 0 by default */

static spinlock_t scull_u_lock = SPIN_LOCK_UNLOCKED; // 初始化自旋锁为0

static int scull_u_open(struct inode *inode, struct file *filp)

{

    struct scull_dev *dev = &scull_u_device; /* device information */

    // 获取自旋锁

    spin_lock(&scull_u_lock);

    // 如果设备已经被打开，且已打开设备的用户不是当前进程的uid或euid，且不具备CAP_DAC_OVERRIDE能力，则释放自旋锁，返回-EBUSY

    // uid表示进程的创建者，euid表示进程对文件和资源的访问权限(具备等同于哪个用户的权限)

    // CAP_DAC_OVERRIDE 越过在文件和目录上的访问限制的能力

    if (scull_u_count &&

            (scull_u_owner != current->uid) &&  /* allow user */

            (scull_u_owner != current->euid) && /* allow whoever did su */

            !capable(CAP_DAC_OVERRIDE)) { /* still allow root */

        spin_unlock(&scull_u_lock);

        return -EBUSY;   /* -EPERM would confuse the user */

    }

    // 如果是第一次打开设备，scull_u_owner设置成当前进程uid

    if (scull_u_count == )

        scull_u_owner = current->uid; /* grab it */

    // 递增打开计数。释放自旋锁。

    scull_u_count++;

    spin_unlock(&scull_u_lock);

/* then, everything else is copied from the bare scull device */

    // 打开设备

    if ((filp->f_flags & O_ACCMODE) == O_WRONLY)

        scull_trim(dev);

    filp->private_data = dev;

    return ;          /* success */

}

static int scull_u_release(struct inode *inode, struct file *filp)

{

    // 获取自旋锁，递减打开计数，释放自旋锁。

    spin_lock(&scull_u_lock);

    scull_u_count--; /* nothing else */

    spin_unlock(&scull_u_lock);

    return ;

}

/*

 * The other operations for the device come from the bare device

 */

struct file_operations scull_user_fops = {

    .owner =      THIS_MODULE,

    .llseek =     scull_llseek,

    .read =       scull_read,

    .write =      scull_write,

    .ioctl =      scull_ioctl,

    .open =       scull_u_open,

    .release =    scull_u_release,

};

/************************************************************************

 *

 * Next, the device with blocking-open based on uid

 */

// 设备阻塞于open TODO

static struct scull_dev scull_w_device;

static int scull_w_count;    /* initialized to 0 by default */

static uid_t scull_w_owner;    /* initialized to 0 by default */

static DECLARE_WAIT_QUEUE_HEAD(scull_w_wait);

static spinlock_t scull_w_lock = SPIN_LOCK_UNLOCKED;

// 判断设备是否可用

static inline int scull_w_available(void)

{

    // 设备没有被打开，或已打开设备的用户是当前进程的uid或euid，或具备CAP_DAC_OVERRIDE能力，则可用

    return scull_w_count ==  ||

        scull_w_owner == current->uid ||

        scull_w_owner == current->euid ||

        capable(CAP_DAC_OVERRIDE);

}

static int scull_w_open(struct inode *inode, struct file *filp)

{

    struct scull_dev *dev = &scull_w_device; /* device information */

    // 获取自旋锁

    spin_lock(&scull_w_lock);

    // 如果设备不可用，则释放自旋锁，等待设备可用后重新申请自旋锁，循环检查设备是否可用

    while (! scull_w_available()) {

        spin_unlock(&scull_w_lock);

        if (filp->f_flags & O_NONBLOCK) return -EAGAIN; // 如果文件以非阻塞模式打开，返回-EAGAIN，让用户层程序再试

        if (wait_event_interruptible (scull_w_wait, scull_w_available())) // 等待设备可用。如果等待过程中有异步信号，返回-ERESTARTSYS

            return -ERESTARTSYS; /* tell the fs layer to handle it */

        spin_lock(&scull_w_lock);

    }

    // 和上面的"uid"设备一样了

    if (scull_w_count == )

        scull_w_owner = current->uid; /* grab it */

    scull_w_count++;

    spin_unlock(&scull_w_lock);

    /* then, everything else is copied from the bare scull device */

    if ((filp->f_flags & O_ACCMODE) == O_WRONLY)

        scull_trim(dev);

    filp->private_data = dev;

    return ;          /* success */

}

static int scull_w_release(struct inode *inode, struct file *filp)

{

    int temp;

    // 申请自旋锁，递减打开计数，释放自旋锁。

    spin_lock(&scull_w_lock);

    scull_w_count--;

    temp = scull_w_count;

    spin_unlock(&scull_w_lock);

    // 如果打开计数是0，唤醒scull_w_wait信号

    if (temp == )

        wake_up_interruptible_sync(&scull_w_wait); /* awake other uid's */

    return ;

}

/*

 * The other operations for the device come from the bare device

 */

struct file_operations scull_wusr_fops = {

    .owner =      THIS_MODULE,

    .llseek =     scull_llseek,

    .read =       scull_read,

    .write =      scull_write,

    .ioctl =      scull_ioctl,

    .open =       scull_w_open,

    .release =    scull_w_release,

};

/************************************************************************

 *

 * Finally the `cloned' private device. This is trickier because it

 * involves list management, and dynamic allocation.

 */

 // 最后是被克隆的私有设备。

 // 这是棘手的，因为涉及列表管理和动态分配。

/* The clone-specific data structure includes a key field */

struct scull_listitem {

    struct scull_dev device;

    dev_t key;

    struct list_head list;

};

// 设备列表，和保护列表的自旋锁

/* The list of devices, and a lock to protect it */

static LIST_HEAD(scull_c_list); // 宏，声明并初始化一个list_head为scull_c_list的静态列表

static spinlock_t scull_c_lock = SPIN_LOCK_UNLOCKED;

/* A placeholder scull_dev which really just holds the cdev stuff. */

// 占位符 scull_dev，实际只有cdev结构 TODO 没看懂。。

static struct scull_dev scull_c_device;   

/* Look for a device or create one if missing */

// 查找指定key的设备，如果没有找到就创建一个新的

static struct scull_dev *scull_c_lookfor_device(dev_t key)

{

    struct scull_listitem *lptr;

    // 遍历scull_listitem，查找指定key的设备

    // 结构 struct scull_listitem lptr 中的成员struct list_head list组成了一个链表，链表头是struct list_head scull_c_list

    list_for_each_entry(lptr,  // pos: the type * to use as a loop cursor

                        &scull_c_list, // head: 要遍历的链表头

                        list) {        // member: the name of the list_struct within the struct

        if (lptr->key == key)

            return &(lptr->device); // 返回scull_dev 成员

    }

    /* not found */

    // 如果没有找到指定key的设备，创建一个scull_listitem结构，加在链表中，返回scull_dev成员

    lptr = kmalloc(sizeof(struct scull_listitem), GFP_KERNEL);

    if (!lptr)

        return NULL;

    /* initialize the device */

    memset(lptr, , sizeof(struct scull_listitem));

    lptr->key = key;

    scull_trim(&(lptr->device)); /* initialize it */

    init_MUTEX(&(lptr->device.sem));

    /* place it in the list */

    list_add(&lptr->list, &scull_c_list);

    return &(lptr->device);

}

static int scull_c_open(struct inode *inode, struct file *filp)

{

    struct scull_dev *dev;

    dev_t key;

    // 如果当前设备没有终端，返回-EINVAL(参数无效)

    if (!current->signal->tty) {

        PDEBUG("Process \"%s\" has no ctl tty\n", current->comm);

        return -EINVAL;

    }

    // 获得当前终端的设备号保存到key中

    key = tty_devnum(current->signal->tty);

    /* look for a scullc device in the list */

    // 从 scull_listitem 中获取指定key的设备(如果没有就创建一个新的返回)-同一终端(key)共用一个设备

    spin_lock(&scull_c_lock);

    dev = scull_c_lookfor_device(key);

    spin_unlock(&scull_c_lock);

    if (!dev)

        return -ENOMEM;

    /* then, everything else is copied from the bare scull device */

    if ( (filp->f_flags & O_ACCMODE) == O_WRONLY)

        scull_trim(dev);

    filp->private_data = dev;

    return ;          /* success */

}

static int scull_c_release(struct inode *inode, struct file *filp)

{

    /*

     * Nothing to do, because the device is persistent.

     * A `real' cloned device should be freed on last close

     */

    return ;

}

/*

 * The other operations for the device come from the bare device

 */

struct file_operations scull_priv_fops = {

    .owner =    THIS_MODULE,

    .llseek =   scull_llseek,

    .read =     scull_read,

    .write =    scull_write,

    .ioctl =    scull_ioctl,

    .open =     scull_c_open,

    .release =  scull_c_release,

};

/************************************************************************

 *

 * And the init and cleanup functions come last

 */

static struct scull_adev_info {

    char *name;

    struct scull_dev *sculldev;

    struct file_operations *fops;

} scull_access_devs[] = {

    { "scullsingle", &scull_s_device, &scull_sngl_fops },

    { "sculluid", &scull_u_device, &scull_user_fops },

    { "scullwuid", &scull_w_device, &scull_wusr_fops },

    { "sullpriv", &scull_c_device, &scull_priv_fops }

};

#define SCULL_N_ADEVS 4

/*

 * Set up a single device.

 */

 // 给定dev_t和scull_adev_info，建立一个设备

static void scull_access_setup (dev_t devno, struct scull_adev_info *devinfo)

{

    struct scull_dev *dev = devinfo->sculldev;

    int err;

    /* Initialize the device structure */

    // 初始化scull_dev结构

    dev->quantum = scull_quantum;

    dev->qset = scull_qset;

    init_MUTEX(&dev->sem);

    /* Do the cdev stuff. */

    // cdev_init 初始化一个cdev结构

    cdev_init(&dev->cdev,  // struct cdev *cdev: 要初始化的结构

              devinfo->fops);  // const struct file_operations *fops: 该设备的 file_operations

    // kobject_set_name 给kobject设置名字

    kobject_set_name(&dev->cdev.kobj,  // struct kobject *kobj: 要设置名字的结构

                    devinfo->name);     // const char *fmt: 用来创建名字的格式化字符串

    dev->cdev.owner = THIS_MODULE;

    // cdev_add() 给系统中添加一个字符设备 &dev->cdev。立即生效。出错时返回一个负的错误码。

    err = cdev_add (&dev->cdev,     // struct cdev *p:  设备的cdev结构

                    devno,          // dev_t dev: 设备的第一个设备号

                    );             // unsigned count: 设备对应的连续次设备号

        /* Fail gracefully if need be */

    // 如果添加设备出错，dev->cdev.kobject引用计数减1

    if (err) {

        printk(KERN_NOTICE "Error %d adding %s\n", err, devinfo->name);

        // kobject_put 递减设备的引用计数。如果引用计数为0，调用 kobject_cleanup()

        kobject_put(&dev->cdev.kobj);  // struct kobject *kobj

    } else

        printk(KERN_NOTICE "%s registered at %x\n", devinfo->name, devno);

}

int scull_access_init(dev_t firstdev)

{

    int result, i;

    /* Get our number space */

    // 注册 SCULL_N_ADEVS 个设备号

    // register_chrdev_region() 注册一系列设备号。成功返回0，失败返回一个负的错误码。

    result = register_chrdev_region (firstdev,      // dev_t from: 要注册的第一个设备号，必须包含主设备号。

                                     SCULL_N_ADEVS,     // unsigned count: 需要的连续设备号个数

                                     "sculla");         // const char *name: 设备或驱动名称

    if (result < ) {

        printk(KERN_WARNING "sculla: device number registration failed\n");

        return ;

    }

    scull_a_firstdev = firstdev;

    /* Set up each device. */

    // 循环给系统中添加 SCULL_N_ADEVS 个字符设备

    for (i = ; i < SCULL_N_ADEVS; i++)

        scull_access_setup (firstdev + i, scull_access_devs + i);

    return SCULL_N_ADEVS;

}

/*

 * This is called by cleanup_module or on failure.

 * It is required to never fail, even if nothing was initialized first

 */

void scull_access_cleanup(void)

{

    struct scull_listitem *lptr, *next;

    int i;

    /* Clean up the static devs */

    // 遍历清除scull_acess_dev中每个静态设备: 移除cdev，释放sculldev数据区

    for (i = ; i < SCULL_N_ADEVS; i++) {

        struct scull_dev *dev = scull_access_devs[i].sculldev;

        // 从系统中删除dev->cdev

        // cdev_del() 从系统中移除一个 cdev ，可能要自己释放结构

        cdev_del(&dev->cdev);  // struct cdev *p: 要移除的cdev结构

        scull_trim(scull_access_devs[i].sculldev);

    }

        /* And all the cloned devices */

    // 遍历清除 scull_listitem中每个cloned设备: 删除list_head，释放sculldev数据区，释放scull_listitem结构内存

    // list_for_each_entry_safe 要求调用者另外提供一个与pos(lptr)同类型的指针next，在for循环中暂存pos的下一个节点的地址，避免因pos节点被释放而造成的断链

    list_for_each_entry_safe(lptr, next, &scull_c_list, list) {

        // list_del 删除链表的entry

        list_del(&lptr->list);  // struct list_head *entry: 要从链表中删除的元素

        scull_trim(&(lptr->device));

        kfree(lptr);

    }

    /* Free up our number space */

    // unregister_chrdev_region 解注册从scull_a_firstdev开始的连续SCULL_N_ADEVS个设备

    unregister_chrdev_region(scull_a_firstdev,  // dev_t from

                            SCULL_N_ADEVS);     // unsigned count

    return;

}

pipe.c

/*

 * pipe.c -- fifo driver for scull

 *

 * Copyright (C) 2001 Alessandro Rubini and Jonathan Corbet

 * Copyright (C) 2001 O'Reilly & Associates

 *

 * The source code in this file can be freely used, adapted,

 * and redistributed in source or binary form, so long as an

 * acknowledgment appears in derived source files.  The citation

 * should list that the code comes from the book "Linux Device

 * Drivers" by Alessandro Rubini and Jonathan Corbet, published

 * by O'Reilly & Associates.   No warranty is attached;

 * we cannot take responsibility for errors or fitness for use.

 *

 */

#include <linux/module.h>

#include <linux/moduleparam.h>

#include <linux/kernel.h>    /* printk(), min() */

#include <linux/slab.h>        /* kmalloc() */

#include <linux/fs.h>        /* everything */

#include <linux/proc_fs.h>

#include <linux/errno.h>    /* error codes */

#include <linux/types.h>    /* size_t */

#include <linux/fcntl.h>

#include <linux/poll.h>

#include <linux/cdev.h>

#include <asm/uaccess.h>

#include "scull.h"        /* local definitions */

struct scull_pipe {

        wait_queue_head_t inq, outq;       /* read and write queues */ // wait_queue_head_t 等待队列头

        char *buffer, *end;                /* begin of buf, end of buf */

        int buffersize;                    /* used in pointer arithmetic */

        char *rp, *wp;                     /* where to read, where to write */

        int nreaders, nwriters;            /* number of openings for r/w */

        struct fasync_struct *async_queue; /* asynchronous readers */ // 异步操作的文件指针结构 TODO

        struct semaphore sem;              /* mutual exclusion semaphore */

        struct cdev cdev;                  /* Char device structure */

};

/* parameters */

static int scull_p_nr_devs = SCULL_P_NR_DEVS;    /* number of pipe devices */

int scull_p_buffer =  SCULL_P_BUFFER;    /* buffer size */

dev_t scull_p_devno;            /* Our first device number */

// 模块加载时，指定管道设备数量、缓存大小

module_param(scull_p_nr_devs, int, );    /* FIXME check perms */

module_param(scull_p_buffer, int, );

static struct scull_pipe *scull_p_devices;

static int scull_p_fasync(int fd, struct file *filp, int mode);

static int spacefree(struct scull_pipe *dev);

/*

 * Open and close

 */

static int scull_p_open(struct inode *inode, struct file *filp)

{

    struct scull_pipe *dev;

    // 获取和inode->i_cdev对应的管道设备(scull_pipe结构)指针

    // container_of: cdev嵌套在struct scull_pipe中，由指向cdev成员的指针，获得指向struct scull_pipe的指针

    dev = container_of(inode->i_cdev,  // ptr: 指向成员的指针

                       struct scull_pipe,   // type: 容器结构的类型

                       cdev);           // member: 成员名称

    filp->private_data = dev;

    if (down_interruptible(&dev->sem))

        return -ERESTARTSYS;

    // 如果dev->buffer为NULL，申请缓存

    if (!dev->buffer) {

        /* allocate the buffer */

        dev->buffer = kmalloc(scull_p_buffer, GFP_KERNEL);

        if (!dev->buffer) {

            up(&dev->sem);

            return -ENOMEM;

        }

    }

    // 给dev成员设初值

    dev->buffersize = scull_p_buffer;

    dev->end = dev->buffer + dev->buffersize;

    dev->rp = dev->wp = dev->buffer; /* rd and wr from the beginning */

    /* use f_mode,not  f_flags: it's cleaner (fs/open.c tells why) */

    // 递增设备打开计数，区分读写模式。

    if (filp->f_mode & FMODE_READ)

        dev->nreaders++;

    if (filp->f_mode & FMODE_WRITE)

        dev->nwriters++;

    up(&dev->sem);

    // 通知内核设备不支持移位llseek

    return nonseekable_open(inode, filp);

}

static int scull_p_release(struct inode *inode, struct file *filp)

{

    struct scull_pipe *dev = filp->private_data;

    /* remove this filp from the asynchronously notified filp's */

    scull_p_fasync(-, filp, ); // TODO

    down(&dev->sem);

    // 设备打开计数减1。打开计数为0时清空设备缓存。

    if (filp->f_mode & FMODE_READ)

        dev->nreaders--;

    if (filp->f_mode & FMODE_WRITE)

        dev->nwriters--;

    if (dev->nreaders + dev->nwriters == ) {

        kfree(dev->buffer);

        dev->buffer = NULL; /* the other fields are not checked on open */

    }

    up(&dev->sem);

    return ;

}

/*

 * Data management: read and write

 */

static ssize_t scull_p_read (struct file *filp, char __user *buf, size_t count,

                loff_t *f_pos)

{

    struct scull_pipe *dev = filp->private_data;

    if (down_interruptible(&dev->sem))

        return -ERESTARTSYS;

    // 如果缓冲区空(读写指针重合)，循环等待缓冲区中有数据可读。

    while (dev->rp == dev->wp) { /* nothing to read */

        up(&dev->sem); /* release the lock */

        if (filp->f_flags & O_NONBLOCK) // 非阻塞打开

            return -EAGAIN;

        PDEBUG("\"%s\" reading: going to sleep\n", current->comm);

        if (wait_event_interruptible(dev->inq, (dev->rp != dev->wp)))   // 异步信号

            return -ERESTARTSYS; /* signal: tell the fs layer to handle it */

        /* otherwise loop, but first reacquire the lock */

        if (down_interruptible(&dev->sem))      // 可被中断地获取信号量

            return -ERESTARTSYS;

    }

    // 数据读取到用户空间。最多读取到dev->end(线程非循环缓冲)

    /* ok, data is there, return something */

    if (dev->wp > dev->rp)

        count = min(count, (size_t)(dev->wp - dev->rp));

    else /* the write pointer has wrapped, return data up to dev->end */

        count = min(count, (size_t)(dev->end - dev->rp));

    if (copy_to_user(buf, dev->rp, count)) {

        up (&dev->sem);

        return -EFAULT;

    }

    // 读位置修改

    dev->rp += count;

    if (dev->rp == dev->end) // 如果读到缓存结尾了，读位置移至缓存开头

        dev->rp = dev->buffer; /* wrapped */

    up (&dev->sem);

    /* finally, awake any writers and return */

    wake_up_interruptible(&dev->outq);

    PDEBUG("\"%s\" did read %li bytes\n",current->comm, (long)count);

    return count;

}

/* Wait for space for writing; caller must hold device semaphore.  On

 * error the semaphore will be released before returning. */

static int scull_getwritespace(struct scull_pipe *dev, struct file *filp)

{

    // 如果缓存已满

    // apacefree返回缓存中可写空间个数

    while (spacefree(dev) == ) { /* full */

        // 初始化等待队列

        DEFINE_WAIT(wait);  // DEFINE_WAIT 创建和初始化一个等待队列。wait是队列入口项的名字。

        up(&dev->sem);

        if (filp->f_flags & O_NONBLOCK) // 如果文件在非阻塞模式，立即返回

            return -EAGAIN;

        PDEBUG("\"%s\" writing: going to sleep\n",current->comm);

        // 添加写等待队列入口，设置进程状态为可中断休眠

        // prepare_to_wait()添加等待队列入口到队列，并设置进程状态

        prepare_to_wait(&dev->outq,  // wait_queue_head_t *queue: 等待队列头

                        &wait,      // wait_queue_t *wait: 进程入口

                        TASK_INTERRUPTIBLE);    // int state: 进程新状态 TASK_INTERRUPTIBLE 可中断休眠

        // 在检查确认仍然需要休眠之后，调用schedule

        if (spacefree(dev) == )

            schedule(); // TODO

        // 条件满足退出后，确保状态为running，同时将进程从等待队列中删除。

        finish_wait(&dev->outq,  // wait_queue_head_t *queue

                    &wait);      // wait_queue_t *wait

        // 如果当前进程有信号处理，返回-ERESTARTSYS

        if (signal_pending(current)) // signal_pending 检查当前进程是否有信号处理，返回不为0表示有信号需要处理

            return -ERESTARTSYS; /* signal: tell the fs layer to handle it */

        // 获取信号量，除非发生中断

        // down_iterruptible尝试获取信号量。如果没有更多任务被允许获取信号量，该任务投入睡眠等待；如果睡眠被信号打断，返回-EINTR；如果成功获取信号量，返回0

        if (down_interruptible(&dev->sem))

            return -ERESTARTSYS;

    }

    return ;

}    

/* How much space is free? */

// 获取dev空闲空间个数

static int spacefree(struct scull_pipe *dev)

{

    if (dev->rp == dev->wp)

        return dev->buffersize - ;

    return ((dev->rp + dev->buffersize - dev->wp) % dev->buffersize) - ; // todo

}

static ssize_t scull_p_write(struct file *filp, const char __user *buf, size_t count,

                loff_t *f_pos)

{

    struct scull_pipe *dev = filp->private_data;

    int result;

    // 获取信号量

    if (down_interruptible(&dev->sem))

        return -ERESTARTSYS;

    /* Make sure there's space to write */

    // 如果没有空间可写，返回错误码

    result = scull_getwritespace(dev, filp);

    if (result)

        return result; /* scull_getwritespace called up(&dev->sem) */

    /* ok, space is there, accept something */

    count = min(count, (size_t)spacefree(dev)); // apacefree 获取空闲空间个数

    if (dev->wp >= dev->rp)

        count = min(count, (size_t)(dev->end - dev->wp)); /* to end-of-buf */

    else /* the write pointer has wrapped, fill up to rp-1 */

        count = min(count, (size_t)(dev->rp - dev->wp - ));

    PDEBUG("Going to accept %li bytes to %p from %p\n", (long)count, dev->wp, buf);

    if (copy_from_user(dev->wp, buf, count)) {

        up (&dev->sem);

        return -EFAULT;

    }

    dev->wp += count;

    if (dev->wp == dev->end)

        dev->wp = dev->buffer; /* wrapped */

    up(&dev->sem);

    /* finally, awake any reader */

    wake_up_interruptible(&dev->inq);  /* blocked in read() and select() */

    /* and signal asynchronous readers, explained late in chapter 5 */

    if (dev->async_queue)

        kill_fasync(&dev->async_queue, SIGIO, POLL_IN);

    PDEBUG("\"%s\" did write %li bytes\n",current->comm, (long)count);

    return count;

}

static unsigned int scull_p_poll(struct file *filp, poll_table *wait)

{

    struct scull_pipe *dev = filp->private_data;

    unsigned int mask = ;

    /*

     * The buffer is circular; it is considered full

     * if "wp" is right behind "rp" and empty if the

     * two are equal.

     */

     // 环形缓冲: wp在rp右侧表示缓冲区满；wp==rp表示空。

    // down() 检查dev->sem是否大于0.如果大于0，将值减1;如果等于0,进程投入睡眠.

    down(&dev->sem);

    // 把当前进程添加到wait参数指定的等待列表中

    poll_wait(filp,   // struct file *filp

              &dev->inq,  // wait_queue_head_t * wait_address

              wait);    // poll_table *p

    poll_wait(filp, &dev->outq, wait);

    // 如果缓存不空，可读

    if (dev->rp != dev->wp)

        mask |= POLLIN | POLLRDNORM;    /* readable */

    // 如果缓存不满，可写

    if (spacefree(dev))

        mask |= POLLOUT | POLLWRNORM;    /* writable */

    // 释放信号量

    up(&dev->sem);

    return mask;

}

static int scull_p_fasync(int fd, struct file *filp, int mode)

{

    struct scull_pipe *dev = filp->private_data;

    // 设置 fasync 队列。

    // fasync_helper()从相关的进程列表中添加或去除入口项。出错返回负数，没有改变返回0，添加删除entry返回正数。

    return fasync_helper(fd, filp, mode, &dev->async_queue);

}

/* FIXME this should use seq_file */

#ifdef SCULL_DEBUG

static void scullp_proc_offset(char *buf, char **start, off_t *offset, int *len)

{

    if (*offset == )

        return;

    if (*offset >= *len) {    /* Not there yet */

        *offset -= *len;

        *len = ;

    }

    else {            /* We're into the interesting stuff now */

        *start = buf + *offset;

        *offset = ;

    }

}

static int scull_read_p_mem(char *buf, char **start, off_t offset, int count,

        int *eof, void *data)

{

    int i, len;

    struct scull_pipe *p;

#define LIMIT (PAGE_SIZE-200)    /* don't print any more after this size */

    *start = buf;

    // len 记录读取字节数

    len = sprintf(buf, "Default buffersize is %i\n", scull_p_buffer);

    // 遍历每一个管道设备，总输出长度不大于LIMIT

    for(i = ; i<scull_p_nr_devs && len <= LIMIT; i++) {

        p = &scull_p_devices[i];

        if (down_interruptible(&p->sem)) // 可中断的申请信号量

            return -ERESTARTSYS;

        len += sprintf(buf+len, "\nDevice %i: %p\n", i, p);

/*        len += sprintf(buf+len, "   Queues: %p %p\n", p->inq, p->outq);*/

        len += sprintf(buf+len, "   Buffer: %p to %p (%i bytes)\n", p->buffer, p->end, p->buffersize);

        len += sprintf(buf+len, "   rp %p   wp %p\n", p->rp, p->wp);

        len += sprintf(buf+len, "   readers %i   writers %i\n", p->nreaders, p->nwriters);

        up(&p->sem);

        // TODO: 移动偏移量?

        scullp_proc_offset(buf, start, &offset, &len);

    }

    *eof = (len <= LIMIT);

    return len;

}

#endif

/*

 * The file operations for the pipe device

 * (some are overlayed with bare scull)

 */

struct file_operations scull_pipe_fops = {

    .owner =    THIS_MODULE,

    .llseek =    no_llseek,

    .read =        scull_p_read,

    .write =    scull_p_write,

    .poll =        scull_p_poll,

    .ioctl =    scull_ioctl,

    .open =        scull_p_open,

    .release =    scull_p_release,

    .fasync =    scull_p_fasync,

};

/*

 * Set up a cdev entry.

 */

static void scull_p_setup_cdev(struct scull_pipe *dev, int index)

{

    int err, devno = scull_p_devno + index;

    cdev_init(&dev->cdev, &scull_pipe_fops);

    dev->cdev.owner = THIS_MODULE;

    err = cdev_add (&dev->cdev, devno, );

    /* Fail gracefully if need be */

    if (err)

        printk(KERN_NOTICE "Error %d adding scullpipe%d", err, index);

}

/*

 * Initialize the pipe devs; return how many we did.

 */

 // 初始化管道设备; 返回管道设备个数。

int scull_p_init(dev_t firstdev)

{

    int i, result;

    // 注册一系列设备号。成功返回0，失败返回一个负的错误码。

    result = register_chrdev_region(firstdev,  // dev_t from: 要注册的第一个设备号，必须包含主设备号

                                    scull_p_nr_devs,    // unsigned count: 需要的连续设备号个数

                                    "scullp");          // const char *name: 设备或驱动名称

    if (result < ) {

        printk(KERN_NOTICE "Unable to get scullp region, error %d\n", result);

        return ;

    }

    scull_p_devno = firstdev;  // 第一个设备号

    // 申请scull_p_nr_devs个scull_pipe设备的存储空间

    scull_p_devices = kmalloc(scull_p_nr_devs * sizeof(struct scull_pipe), GFP_KERNEL);

    if (scull_p_devices == NULL) {

        unregister_chrdev_region(firstdev, scull_p_nr_devs);

        return ;

    }

    memset(scull_p_devices, , scull_p_nr_devs * sizeof(struct scull_pipe));

    for (i = ; i < scull_p_nr_devs; i++) {

        // 初始化读写等待队列头

        init_waitqueue_head(&(scull_p_devices[i].inq));

        init_waitqueue_head(&(scull_p_devices[i].outq));

        // 初始化互斥信号量，sem置1

        init_MUTEX(&scull_p_devices[i].sem);

        // 建立字符设备入口

        scull_p_setup_cdev(scull_p_devices + i, i);

    }

#ifdef SCULL_DEBUG

    create_proc_read_entry("scullpipe", , NULL, scull_read_p_mem, NULL);

#endif

    return scull_p_nr_devs;

}

/*

 * This is called by cleanup_module or on failure.

 * It is required to never fail, even if nothing was initialized first

 */

void scull_p_cleanup(void)

{

    int i;

#ifdef SCULL_DEBUG

    remove_proc_entry("scullpipe", NULL);

#endif

    if (!scull_p_devices)

        return; /* nothing else to release */

    for (i = ; i < scull_p_nr_devs; i++) {

        cdev_del(&scull_p_devices[i].cdev);

        kfree(scull_p_devices[i].buffer);

    }

    kfree(scull_p_devices);

    unregister_chrdev_region(scull_p_devno, scull_p_nr_devs);

    scull_p_devices = NULL; /* pedantic */

}