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><A
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>Chapter 5. The /proc File System</H1
><DIV
CLASS="SECT1"
><H1
CLASS="SECT1"
><A
NAME="AEN724"
></A
>The /proc File System</H1
><A
NAME="AEN726"
></A
><A
NAME="AEN729"
></A
><P
>In Linux there is an additional mechanism for the kernel and kernel modules to send information to processes --- the
	<TT
CLASS="FILENAME"
>/proc</TT
> file system.  Originally designed to allow easy access to information about
	processes (hence the name), it is now used by every bit of the kernel which has something interesting to report, such as
	<TT
CLASS="FILENAME"
>/proc/modules</TT
> which has the list of modules and <TT
CLASS="FILENAME"
>/proc/meminfo</TT
> which has memory usage
	statistics.</P
><A
NAME="AEN737"
></A
><A
NAME="AEN740"
></A
><P
>The method to use the proc file system is very similar to the one used with device drivers --- you create a structure
	with all the information needed for the <TT
CLASS="FILENAME"
>/proc</TT
> file, including pointers to any handler
	functions (in our case there is only one, the one called when somebody attempts to read from the <TT
CLASS="FILENAME"
>/proc</TT
> file). Then, <TT
CLASS="FUNCTION"
>init_module</TT
> registers the structure with the kernel and
	<TT
CLASS="FUNCTION"
>cleanup_module</TT
> unregisters it.</P
><P
>The reason we use <TT
CLASS="FUNCTION"
>proc_register_dynamic</TT
><A
NAME="AEN750"
HREF="#FTN.AEN750"
><SPAN
CLASS="footnote"
>[1]</SPAN
></A
> is because we don't want to determine the inode number
	used for our file in advance, but to allow the kernel to determine it to prevent clashes. Normal file systems are located on a
	disk, rather than just in memory (which is where <TT
CLASS="FILENAME"
>/proc</TT
> is), and in that case the inode
	number is a pointer to a disk location where the file's index-node (inode for short) is located. The inode contains
	information about the file, for example the file's permissions, together with a pointer to the disk location or locations
	where the file's data can be found.</P
><A
NAME="AEN753"
></A
><A
NAME="AEN756"
></A
><A
NAME="AEN759"
></A
><P
>Because we don't get called when the file is opened or closed, there's no where for us to put
	<TT
CLASS="VARNAME"
>MOD_INC_USE_COUNT</TT
> and <TT
CLASS="VARNAME"
>MOD_DEC_USE_COUNT</TT
> in this module, and if the file is opened and
	then the module is removed, there's no way to avoid the consequences. In the next chapter we'll see a harder to implement, but
	more flexible, way of dealing with <TT
CLASS="FILENAME"
>/proc</TT
> files which will allow us to protect against
	this problem as well.</P
><DIV
CLASS="EXAMPLE"
><A
NAME="AEN765"
></A
><P
><B
>Example 5-1. procfs.c</B
></P
><PRE
CLASS="PROGRAMLISTING"
>/*  procfs.c -  create a "file" in /proc 
 */

#include &#60;linux/kernel.h&#62;   /* We're doing kernel work */
#include &#60;linux/module.h&#62;   /* Specifically, a module */

/* Deal with CONFIG_MODVERSIONS */
#if CONFIG_MODVERSIONS==1
#define MODVERSIONS
#include &#60;linux/modversions.h&#62;
#endif        


/* Necessary because we use the proc fs */
#include &#60;linux/proc_fs.h&#62;



/* In 2.2.3 /usr/include/linux/version.h includes a 
 * macro for this, but 2.0.35 doesn't - so I add it 
 * here if necessary. */
#ifndef KERNEL_VERSION
#define KERNEL_VERSION(a,b,c) ((a)*65536+(b)*256+(c))
#endif



/* Put data into the proc fs file.

   Arguments
   =========
   1. The buffer where the data is to be inserted, if 
      you decide to use it.
   2. A pointer to a pointer to characters. This is 
      useful if you don't want to use the buffer 
      allocated by the kernel.
   3. The current position in the file. 
   4. The size of the buffer in the first argument.  
   5. Zero (for future use?).


   Usage and Return Value
   ======================
   If you use your own buffer, like I do, put its 
   location in the second argument and return the 
   number of bytes used in the buffer.

   A return value of zero means you have no further 
   information at this time (end of file). A negative 
   return value is an error condition.
   

   For More Information
   ==================== 
   The way I discovered what to do with this function 
   wasn't by reading documentation, but by reading the 
   code which used it. I just looked to see what uses 
   the get_info field of proc_dir_entry struct (I used a 
   combination of find and grep, if you're interested), 
   and I saw that  it is used in &#60;kernel source 
   directory&#62;/fs/proc/array.c.

   If something is unknown about the kernel, this is 
   usually the way to go. In Linux we have the great 
   advantage of having the kernel source code for 
   free - use it.
 */
int procfile_read(char *buffer, 
		  char **buffer_location, 
		  off_t offset, 
		  int buffer_length, 
		  int zero)
{
  int len;  /* The number of bytes actually used */

  /* This is static so it will still be in memory 
   * when we leave this function */
  static char my_buffer[80];  

  static int count = 1;

  /* We give all of our information in one go, so if the 
   * user asks us if we have more information the 
   * answer should always be no. 
   *
   * This is important because the standard read 
   * function from the library would continue to issue 
   * the read system call until the kernel replies
   * that it has no more information, or until its 
   * buffer is filled.
   */
  if (offset &#62; 0)
    return 0;

  /* Fill the buffer and get its length */
  len = sprintf(my_buffer, 
    "For the %d%s time, go away!\n", count,
    (count % 100 &#62; 10 &#38;&#38; count % 100 &#60; 14) ? "th" : 
      (count % 10 == 1) ? "st" :
        (count % 10 == 2) ? "nd" :
          (count % 10 == 3) ? "rd" : "th" );
  count++;

  /* Tell the function which called us where the 
   * buffer is */
  *buffer_location = my_buffer;

  /* Return the length */
  return len;
}


struct proc_dir_entry Our_Proc_File = 
  {
    0, /* Inode number - ignore, it will be filled by 
        * proc_register[_dynamic] */
    4, /* Length of the file name */
    "test", /* The file name */
    S_IFREG | S_IRUGO, /* File mode - this is a regular 
                        * file which can be read by its 
                        * owner, its group, and everybody
                        * else */
    1,	/* Number of links (directories where the 
         * file is referenced) */
    0, 0,  /* The uid and gid for the file - we give it 
            * to root */
    80, /* The size of the file reported by ls. */
    NULL, /* functions which can be done on the inode 
           * (linking, removing, etc.) - we don't 
           * support any. */
    procfile_read, /* The read function for this file, 
                    * the function called when somebody 
                    * tries to read something from it. */
    NULL /* We could have here a function to fill the 
          * file's inode, to enable us to play with 
          * permissions, ownership, etc. */
  }; 





/* Initialize the module - register the proc file */
int init_module()
{
  /* Success if proc_register[_dynamic] is a success, 
   * failure otherwise. */
#if LINUX_VERSION_CODE &#62; KERNEL_VERSION(2,2,0)
  /* In version 2.2, proc_register assign a dynamic 
   * inode number automatically if it is zero in the 
   * structure , so there's no more need for 
   * proc_register_dynamic
   */
  return proc_register(&#38;proc_root, &#38;Our_Proc_File);
#else
  return proc_register_dynamic(&#38;proc_root, &#38;Our_Proc_File);
#endif
 
  /* proc_root is the root directory for the proc 
   * fs (/proc). This is where we want our file to be 
   * located. 
   */
}


/* Cleanup - unregister our file from /proc */
void cleanup_module()
{
  proc_unregister(&#38;proc_root, Our_Proc_File.low_ino);
}  &#13;</PRE
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><H3
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>Notes</H3
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><A
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HREF="c722.htm#AEN750"
><SPAN
CLASS="footnote"
>[1]</SPAN
></A
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><P
>In version 2.0, in version 2.2 this is done
	for us automatically if we set the inode to zero.</P
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