I am already aware of real user id. It is the unique number for a user in the system.
In my system, My uid
is
$ echo $UID
1014
I'll try to explain step by step with some examples.
Short background
Each process has its own 'Process credentials' which includes attributes like PID
, the PPID
, PGID
,session ID
and also the real and effective user and group IDs:
RUID
, EUID
, RGID
, EGID
.
We'll focus on those.
Part 1: Understand UID and GID
Now I'll log into a shell with my credentials and run:
$ grep $LOGNAME /etc/passwd
rotem:x:1000:1000:rotem,,,:/home/rotem:/bin/bash
You can see my logname (rotem), the UID and GID which are both 1000, and other details like the shell I'm logged into.
Part 2: Understand RUID and RGID
Every process has an owner and belongs to a group.
In our shell, every process that we'll now run will inherit the privileges of my user account and will run with the same UID and GID.
Lets run a simple command to check it:
$ sleep 10 & ps aux | grep 'sleep'
And check for the process UID and GID:
$ stat -c "%u %g" /proc/$pid/
1000 1000
Those are the Real user ID (RUID
) and real group ID (RGID
) of the process.
(*) Check other options to view the UID and GID and ways to get this in one-liner in.
For now, accept the fact that the EUID
and EGID
attributes are 'redundant' and just equals to RUID
and RGID
behind the scenes.
Part 3: Understand EUID and EGID
Let's take the ping
command as an example.
Search for the binary location with the which
command then run ls -la
:
-rwsr-xr-x 1 root root 64424 Mar 10 2017 ping
You can see that owner and group of the file are root
. This is because the ping
command needs to open up a socket and the Linux kernel demands root
privilege for that.
But how can I use ping
if I don't have root
privilege?
Notice the 's' letter instead of 'x' in the owner part of the file permission.
This is a special permission bit for specific binary executable files (like ping
and sudo
) which is known as setuid.
This is where EUID
and EGID
comes into play.
What will happen is when a setuid binary like ping
executes, the process changes its Effective User ID (EUID
) from the default RUID
to the owner of this special binary executable file which in this case is - root
.
This is all done by the simple fact that this file has the setuid
bit.
The kernel makes the decision whether this process has the privilege by looking on the EUID
of the process. Because now the EUID
points to root
, the operation won't be rejected by the kernel.
Notice: On latest Linux releases the output of the ping
command will look different because of the fact that they adopted the Linux Capabilities approach instead of this setuid approach - for those who are not familiar - read here.
Part 4: What about SUID and SGID?
The Saved user ID (SUID
) is being used when a privileged process is running (as root
for example) and it needs to do some unprivileged tasks.
In that case, the effective UID (EUID
) from before will be saved inside SUID
and then changed to an unprivileged task. When the unprivileged task is completed
the EUID
will be taken from the value of SUID
and switch back to privileged account.
The distinction between a real and an effective user id is made because you may have the need to temporarily take another user's identity (most of the time, that would be root
, but it could be any user). If you only had one user id, then there would be no way of changing back to your original user id afterwards (other than taking your word for granted, and in case you are root
, using root
's privileges to change to any user).
So, the real user id is who you really are (the one who owns the process), and the effective user id is what the operating system looks at to make a decision whether or not you are allowed to do something (most of the time, there are some exceptions).
When you log in, the login shell sets both the real and effective user id to the same value (your real user id) as supplied by the password file.
Now, it also happens that you execute a setuid program, and besides running as another user (e.g. root
) the setuid program is also supposed to do something on your behalf. How does this work?
After executing the setuid program, it will have your real id (since you're the process owner) and the effective user id of the file owner (for example root
) since it is setuid.
The program does whatever magic it needs to do with superuser privileges and then wants to do something on your behalf. That means, attempting to do something that you shouldn't be able to do should fail. How does it do that? Well, obviously by changing its effective user id to the real user id!
Now that setuid program has no way of switching back since all the kernel knows is your id and... your id. Bang, you're dead.
This is what the saved set-user id is for.