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(Should advanced topics be here? I think it would be nice to have some of these, just to show people the possibilities and give some conceptual explanation that won't really be in a reference manual. Also it always feels nice to make it to a chapter called "advanced topics". Self-esteem booster for the newbie. :)
Automate simple tasks.
Ideas?
Each file on your system is represented by an inode (for Information Node; pronounced "eye-node"): an inode contains all the information about the file. However, the inode is not directly visible. Instead, each inode is linked into the filesystem by one or more hard links. Hard links contain the name of the file, and the inode number. The inode contains the file itself, i.e., the location of the information being stored on disk, its access permissions, the type of the file, and so on. The system can find any inode once it has the inode number.
A single file can have more than one hard link. What this means is that multiple filenames refer to the same file (that is, they are associated with the same inode number). However, you can't make hard links across filesystems: all hard references to a particular file (inode) must be on the same filesystem. This is because each filesystem has its own set of inodes, and there can be duplicate inode numbers between filesystems.
Since all hard links to a given inode are referring to the same file, you can make changes to the file, referring to it by one name, and then see those changes when referring to it by a different name. Try this:
cd; echo "hello" > firstlink
cd to your home directory and create a file called firstlink containing the word "hello". What you've actually done is redirect the output of echo (echo just echoes back what you give to it), placing the output in firstlink. See the chapter on shells for a full explanation.
cat firstlink
Confirm the contents of firstlink.
ln firstlink secondlink
Create a hard link: secondlink now points to the same inode as firstlink.
cat secondlink
Confirm that secondlink is the same as firstlink
ls -l
Notice that the number of hard links listed for firstlink and secondlink is 2.
echo "change" >> secondlink
This is another shell redirection trick - don't worry about the details. We've appended the word "change" to secondlink. Confirm this with cat secondlink.
cat firstlink
firstlink also has the word "change" appended! It's because firstlink and secondlink refer to the same file. It doesn't matter what you call it when you change it.
chmod a+rwx firstlink
Change permissions on firstlink. Do ls -l to confirm that permissions on secondlink were also changed. This means that permissions information is stored in the inode, not in links.
rm firstlink
Delete this link. This is a subtlety of rm --- it really removes links, not files. Now type ls -l and notice that secondlink is still there. Also notice that the number of hard links for secondlink has been reduced to one.
rm secondlink
Delete the other link. When there are no more links to a file, Linux deletes the file itself, that is, its inode.
All files work like this --- even special types of files such as devices (e.g. /dev/hda).
A directory is simply a list of filenames and inode numbers, that is, a list of hard links. When you create a hard link, you're just adding a name-number pair to a directory. When you delete a file, you're just removing a hard link from a directory.
One detail we've been concealing up to now is that the Linux kernel considers nearly everything to be a file. That includes directories and devices: they're just special kinds of files.
As you may remember, the first character of an ls -l display represents the type of the file. For an ordinary file, this will be simply -. Other possibilities are:
d (directory)
l (symbolic link)
b (block device)
c (character device)
p (named pipe)
s (socket)
Symbolic links (also called symlinks or soft links) are the other kind of link besides hard links. A symlink is a special file that "points to" a hard link on any mounted filesystem. When you try to read the contents of a symlink, it gives the contents of the file it's pointing to rather than the contents of the symlink itself. Since directories, devices, and other symlinks are types of files, you can point a symlink at any of those things.
So a hard link is a filename and an inode number. A file is really an inode: a location on disk, file type, permissions mode, etc. A symlink is an inode that contains the name of a hard link. A symlink pairs one filename with a second filename, while a hard link pairs a filename with an inode number.
All hard links to the same file have equal status. That is, one is as good as the other; if you perform any operation on one it's just the same as performing that operation on any of the others. This is because the hard links all refer to the same inode. Operations on symlinks, on the other hand, sometimes affect the symlink's own inode (the one containing the name of a hard link) and sometimes affect the hard link being pointed to.
There are a number of important differences between symlinks and hard links:
Symlinks can cross filesystems. This is because they contain complete filenames, starting with the root directory, and all complete filenames are unique. Since hard links point to inode numbers, and inode numbers are unique only within a single filesystem, they would be ambiguous if the filesystem wasn't known.
You can make symlinks to directories, but you can't make hard links to them. Each directory has hard links --- its listing in its parent directory, its . entry, and the .. entry in each of its subdirectories --- but to impose order on the filesystem, no other hard links to directories are allowed. Consequently, the number of files in a directory is equal to the number of hard links to that directory minus two (you subtract the directory's name and the . link).
You can only make a hard link to a file that exists, because there must be an inode number to refer to. However, you can make a symlink to any filename, whether or not there actually is such a filename.
Removing a symlink removes only the link. It has no effect on the linked-to file. Removing the only hard link to a file removes the file.
Try this:
cd; ln -s /tmp/me MyTmp
cd to your home directory. ln with the -s option makes a symbolic link; in this case, one called MyTmp which points to the filename /tmp/me.
ls -l MyTmp
Output should look like this:
lrwxrwxrwx 1 havoc havoc 7 Dec 6 12:50 MyTmp -> /tmp/me
The date and user/group names will be different for you, of course. Notice that the file type is l, indicating that this is a symbolic link. Also notice the permissions - symbolic links always have these permissions. If you attempt to chmod a symlink, you'll actually change the permissions on the file being pointed to.
chmod 700 MyTmp
You will get a "No such file or directory" error, because the file /tmp/me doesn't exist. Notice that you could create a symlink to it anyway.
mkdir /tmp/me
Create the directory /tmp/me.
chmod 700 MyTmp
Should work now.
touch MyTmp/myfile
Create a file in MyTmp.
ls /tmp/me
The file was actually created in /tmp/me.
rm MyTmp
Remove the symbolic link. Notice that this removes the link, not what it points to. Thus you use rm not rmdir.
rm /tmp/me/myfile; rmdir /tmp/me
Clean up after ourselves.
Device files refer to physical or virtual devices on your system, such as your hard disk, video card, screen, or keyboard. An example of a virtual device is the console, represented by /dev/console.
There are two kinds of devices: character devices can be accessed one character at a time, that is, the smallest unit of data which can be written to or read from the device is a character (byte).
Block devices must be accessed in larger units called blocks, which contain a number of characters. Your hard disk is a block device.
You can read and write device files just as you can from other kinds of files, though the file may well contain some strange incomprehensible-to-humans gibberish. Writing random data to these files is probably a Bad Idea. Sometimes it's useful, though: for example, you can dump a postscript file into the printer device /dev/lp0, or send modem commands to the device file for the appropriate serial port.
/dev/null is a special device file that discards anything you write to it. If you don't want something, throw it in /dev/null. It's essentially a bottomless pit. If you read /dev/null, you'll get an end-of-file (EOF) character immediately. /dev/zero is similar, only if you read from it you get the \0 character (not the same as the number zero).
A named pipe is a file that acts like a pipe. You put something into the file, and it comes out the other end. Thus it's called a FIFO, or First-In-First-Out: the first thing you put in the pipe is the first thing to come out the other end.
If you write to a named pipe, the process which is writing to the pipe doesn't terminate until the information being written is read from the pipe. If you read from a named pipe, the reading process waits until there's something to read before terminating. The size of the pipe is always zero --- it doesn't store data, it just links two processes like the shell |. However, since this pipe has a name, the two processes don't have to be on the same command line or even be run by the same user.
You can try it by doing the following:
cd; mkfifo mypipe
Makes the pipe.
echo "hello" > mypipe &
Puts a process in the background which tries to write "hello" to the pipe. Notice that the process doesn't return from the background; it is waiting for someone to read from the pipe.
cat mypipe
At this point the echo process should return, since cat read from the pipe, and the cat process will print hello.
rm mypipe
You can delete pipes just like any other file.
Sockets are similar to pipes, only they work over the network. This is how your computer does networking: you may have heard of "WinSock", which is sockets for Windows.
We won't go into these further, because you probably won't have occasion to use them unless you're programming. However, if you see a file marked with type s on your computer, you know what it is.
The Linux kernel makes a special filesystem available, which is mounted under /proc on Debian systems. This is a "pseudo-filesystem" --- it doesn't really exist on any of your physical devices.
The proc filesystem contains information about the system and running processes. Some of the "files" in /proc are reasonably understandable to humans (try typing cat /proc/meminfo or cat /proc/cpuinfo) while some others are arcane collections of numbers. Often, system utilities use these to gather information and present it to you in a more understandable way.
People frequently panic when they notice one file in particular --- /proc/kcore --- which is generally huge. This is (more or less) a copy of the contents of your computer's memory. It's used to debug the kernel. It doesn't actually exist anywhere, so don't worry about its size.
If you want to know about all the things in /proc, type man 5 proc.
Earlier in this chapter, we briefly mentioned that you can set file permissions using numbers. The numeric notation is called an absolute mode, as opposed to the symbolic notation (e.g. u+rx) which is often called a relative mode. This is because the number specifies an exact mode to set, and the symbol just specifies a change to make (e.g. "add user read and execute permissions").
The numeric mode is a series of four octal digits or twelve binary digits. Each octal (base eight) digit represents three binary digits: one octal digit and three binary digits are two ways to represent the decimal digits 0 through 7.
Deriving a particular mode is pretty straightforward. You simply add up the modes you want to combine, or subtract modes you don't want. For example, user permissions, with only read permission turned on, would be 100 in binary. User permissions with write only would be 010 binary. User permissions with read and write both turned on would be 100 + 010 = 110. Alternatively, you could put it in octal: 4 + 2 = 6.
For the full mode, simply add up digits from this table:
0001 others, execute 0002 others, write 0004 others, read 0010 group, execute 0020 group, write 0040 group, read 0100 user, execute 0200 user, write 0400 user, read 1000 sticky bit 2000 set group id 4000 set user id
To use the table, first decide what permissions you want to set. Then add up the numbers for those permissions. The total is your mode. For example, to get mode 0755:
0001 o=x 0004 o=r 0010 g=x 0040 g=r 0100 u=x 0200 u=w + 0400 u=r ------- 0755 u=rwx go=rw
You'd actually call this mode simply 755, without the leading 0, because chmod automatically adds zeroes at the beginning of the mode --- 7 means mode 0007.
To set a file to 755, you'd type chmod 755 myfile.
755 is a very common mode for directories, as it allows anyone to use the directory but only the owner to create and delete files in the directory. 644 is the analogous mode for files, and it is also very common. It allows anyone to use the file but only the owner can change it. For executable files, 755 is a common mode; this is just 644 plus execute permissions (644 + 111 = 755).
A useful tip?
cp -a and variants on the theme.
how to copy an old system to a new one.
FIXME whoops, I also listed this topic under Backup Tools. need to decide.
fsck, dd, fdisk, etc.
what package is a file in?
MSDOS vs. Mac vs. Unix text files
sync
How, what, and why
The basics of security from a user standpoint. Maintaining one's privacy. What other users can see of your account.
Something about the Linux programming environment. Aimed at, say, people taking CS101. Nothing on how to program, just Emacs, gcc, gdb, ddd, etc. as programming tools.
Likely based on debug.tex
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Debian Tutorial (Obsolete Documentation)
29 Dezember 2009[email protected]