[p5sagit/p5-mst-13.2.git] / pod / perlsec.pod

=head1 NAME

perlsec - Perl security

=head1 DESCRIPTION

Perl is designed to make it easy to write secure setuid and setgid
scripts.  Unlike shells, which are based on multiple substitution
passes on each line of the script, Perl uses a more conventional
evaluation scheme with fewer hidden "gotchas".  Additionally, since the
language has more built-in functionality, it has to rely less upon
external (and possibly untrustworthy) programs to accomplish its
purposes.

Beyond the obvious problems that stem from giving special privileges to
such flexible systems as scripts, on many operating systems, setuid
scripts are inherently insecure right from the start.  This is because
that between the time that the kernel opens up the file to see what to
run, and when the now setuid interpreter it ran turns around and reopens
the file so it can interpret it, things may have changed, especially if
you have symbolic links on your system.

Fortunately, sometimes this kernel "feature" can be disabled.
Unfortunately, there are two ways to disable it.  The system can simply
outlaw scripts with the setuid bit set, which doesn't help much.
Alternately, it can simply ignore the setuid bit on scripts.  If the
latter is true, Perl can emulate the setuid and setgid mechanism when it
notices the otherwise useless setuid/gid bits on Perl scripts.  It does
this via a special executable called B<suidperl> that is automatically
invoked for you if it's needed.

If, however, the kernel setuid script feature isn't disabled, Perl will
complain loudly that your setuid script is insecure.  You'll need to
either disable the kernel setuid script feature, or put a C wrapper around
the script.  See the program B<wrapsuid> in the F<eg> directory of your
Perl distribution for how to go about doing this.

There are some systems on which setuid scripts are free of this inherent
security bug.  For example, recent releases of Solaris are like this.  On
such systems, when the kernel passes the name of the setuid script to open
to the interpreter, rather than using a pathname subject to mettling, it
instead passes /dev/fd/3.  This is a special file already opened on the
script, so that there can be no race condition for evil scripts to
exploit.  On these systems, Perl should be compiled with
C<-DSETUID_SCRIPTS_ARE_SECURE_NOW>.  The B<Configure> program that builds
Perl tries to figure this out for itself.

When Perl is executing a setuid script, it takes special precautions to
prevent you from falling into any obvious traps.  (In some ways, a Perl
script is more secure than the corresponding C program.)  Any command line
argument, environment variable, or input is marked as "tainted", and may
not be used, directly or indirectly, in any command that invokes a
subshell, or in any command that modifies files, directories, or
processes.  Any variable that is set within an expression that has
previously referenced a tainted value also becomes tainted (even if it is
logically impossible for the tainted value to influence the variable).
For example:

    $foo = shift;		# $foo is tainted
    $bar = $foo,'bar';		# $bar is also tainted
    $xxx = <>;			# Tainted
    $path = $ENV{'PATH'};	# Tainted, but see below
    $abc = 'abc';		# Not tainted

    system "echo $foo";		# Insecure
    system "/bin/echo", $foo;	# Secure (doesn't use sh)
    system "echo $bar";		# Insecure
    system "echo $abc";		# Insecure until PATH set

    $ENV{'PATH'} = '/bin:/usr/bin';
    $ENV{'IFS'} = '' if $ENV{'IFS'} ne '';

    $path = $ENV{'PATH'};	# Not tainted
    system "echo $abc";		# Is secure now!

    open(FOO,"$foo");		# OK
    open(FOO,">$foo"); 		# Not OK

    open(FOO,"echo $foo|");	# Not OK, but...
    open(FOO,"-|") || exec 'echo', $foo;	# OK

    $zzz = `echo $foo`;		# Insecure, zzz tainted

    unlink $abc,$foo;		# Insecure
    umask $foo;			# Insecure

    exec "echo $foo";		# Insecure
    exec "echo", $foo;		# Secure (doesn't use sh)
    exec "sh", '-c', $foo;	# Considered secure, alas

The taintedness is associated with each scalar value, so some elements
of an array can be tainted, and others not.

If you try to do something insecure, you will get a fatal error saying
something like "Insecure dependency" or "Insecure PATH".  Note that you
can still write an insecure system call or exec, but only by explicitly
doing something like the last example above.  You can also bypass the
tainting mechanism by referencing subpatterns--Perl presumes that if
you reference a substring using $1, $2, etc, you knew what you were
doing when you wrote the pattern:

    $ARGV[0] =~ /^-P(\w+)$/;
    $printer = $1;		# Not tainted

This is fairly secure since C<\w+> doesn't match shell metacharacters.
Use of C</.+/> would have been insecure, but Perl doesn't check for that,
so you must be careful with your patterns.  This is the I<ONLY> mechanism
for untainting user supplied filenames if you want to do file operations
on them (unless you make C<$E<gt>> equal to C<$E<lt>> ).

For "Insecure PATH" messages, you need to set C<$ENV{'PATH}'> to a known
value, and each directory in the path must be non-writable by the world.
A frequently voiced gripe is that you can get this message even
if the pathname to an executable is fully qualified.  But Perl can't
know that the executable in question isn't going to execute some other
program depending on the PATH.

It's also possible to get into trouble with other operations that don't
care whether they use tainted values.  Make judicious use of the file
tests in dealing with any user-supplied filenames.  When possible, do
opens and such after setting C<$E<gt> = $E<lt>>.  (Remember group IDs,
too!) Perl doesn't prevent you from opening tainted filenames for reading,
so be careful what you print out.  The tainting mechanism is intended to
prevent stupid mistakes, not to remove the need for thought.
Commit	Line	Data
a0d0e21e	1	=head1 NAME
	2
	3	perlsec - Perl security
	4
	5	=head1 DESCRIPTION
	6
	7	Perl is designed to make it easy to write secure setuid and setgid
	8	scripts. Unlike shells, which are based on multiple substitution
	9	passes on each line of the script, Perl uses a more conventional
	10	evaluation scheme with fewer hidden "gotchas". Additionally, since the
	11	language has more built-in functionality, it has to rely less upon
	12	external (and possibly untrustworthy) programs to accomplish its
	13	purposes.
	14
	15	Beyond the obvious problems that stem from giving special privileges to
	16	such flexible systems as scripts, on many operating systems, setuid
	17	scripts are inherently insecure right from the start. This is because
	18	that between the time that the kernel opens up the file to see what to
	19	run, and when the now setuid interpreter it ran turns around and reopens
	20	the file so it can interpret it, things may have changed, especially if
	21	you have symbolic links on your system.
	22
	23	Fortunately, sometimes this kernel "feature" can be disabled.
	24	Unfortunately, there are two ways to disable it. The system can simply
	25	outlaw scripts with the setuid bit set, which doesn't help much.
	26	Alternately, it can simply ignore the setuid bit on scripts. If the
	27	latter is true, Perl can emulate the setuid and setgid mechanism when it
	28	notices the otherwise useless setuid/gid bits on Perl scripts. It does
	29	this via a special executable called B<suidperl> that is automatically
	30	invoked for you if it's needed.
	31
	32	If, however, the kernel setuid script feature isn't disabled, Perl will
	33	complain loudly that your setuid script is insecure. You'll need to
	34	either disable the kernel setuid script feature, or put a C wrapper around
	35	the script. See the program B<wrapsuid> in the F<eg> directory of your
	36	Perl distribution for how to go about doing this.
	37
	38	There are some systems on which setuid scripts are free of this inherent
	39	security bug. For example, recent releases of Solaris are like this. On
	40	such systems, when the kernel passes the name of the setuid script to open
	41	to the interpreter, rather than using a pathname subject to mettling, it
	42	instead passes /dev/fd/3. This is a special file already opened on the
	43	script, so that there can be no race condition for evil scripts to
	44	exploit. On these systems, Perl should be compiled with
	45	C<-DSETUID_SCRIPTS_ARE_SECURE_NOW>. The B<Configure> program that builds
	46	Perl tries to figure this out for itself.
	47
	48	When Perl is executing a setuid script, it takes special precautions to
	49	prevent you from falling into any obvious traps. (In some ways, a Perl
	50	script is more secure than the corresponding C program.) Any command line
	51	argument, environment variable, or input is marked as "tainted", and may
	52	not be used, directly or indirectly, in any command that invokes a
	53	subshell, or in any command that modifies files, directories, or
	54	processes. Any variable that is set within an expression that has
	55	previously referenced a tainted value also becomes tainted (even if it is
	56	logically impossible for the tainted value to influence the variable).
	57	For example:
	58
	59	$foo = shift; # $foo is tainted
	60	$bar = $foo,'bar'; # $bar is also tainted
	61	$xxx = <>; # Tainted
	62	$path = $ENV{'PATH'}; # Tainted, but see below
	63	$abc = 'abc'; # Not tainted
	64
65	system "echo $foo"; # Insecure
66	system "/bin/echo", $foo; # Secure (doesn't use sh)
67	system "echo $bar"; # Insecure
68	system "echo $abc"; # Insecure until PATH set
69
70	$ENV{'PATH'} = '/bin:/usr/bin';
71	$ENV{'IFS'} = '' if $ENV{'IFS'} ne '';
72
73	$path = $ENV{'PATH'}; # Not tainted
74	system "echo $abc"; # Is secure now!
75
76	open(FOO,"$foo"); # OK
77	open(FOO,">$foo"); # Not OK
78
79	open(FOO,"echo $foo\|"); # Not OK, but...
80	open(FOO,"-\|") \|\| exec 'echo', $foo; # OK
81
82	$zzz = `echo $foo`; # Insecure, zzz tainted
83
84	unlink $abc,$foo; # Insecure
85	umask $foo; # Insecure
86
87	exec "echo $foo"; # Insecure
88	exec "echo", $foo; # Secure (doesn't use sh)
89	exec "sh", '-c', $foo; # Considered secure, alas
90
91	The taintedness is associated with each scalar value, so some elements
92	of an array can be tainted, and others not.
93
94	If you try to do something insecure, you will get a fatal error saying
95	something like "Insecure dependency" or "Insecure PATH". Note that you
96	can still write an insecure system call or exec, but only by explicitly
97	doing something like the last example above. You can also bypass the
98	tainting mechanism by referencing subpatterns--Perl presumes that if
99	you reference a substring using $1, $2, etc, you knew what you were
100	doing when you wrote the pattern:
101
102	$ARGV[0] =~ /^-P(\w+)$/;
103	$printer = $1; # Not tainted
104
105	This is fairly secure since C<\w+> doesn't match shell metacharacters.
106	Use of C</.+/> would have been insecure, but Perl doesn't check for that,
107	so you must be careful with your patterns. This is the I<ONLY> mechanism
108	for untainting user supplied filenames if you want to do file operations
109	on them (unless you make C<$E<gt>> equal to C<$E<lt>> ).
110
111	For "Insecure PATH" messages, you need to set C<$ENV{'PATH}'> to a known
112	value, and each directory in the path must be non-writable by the world.
113	A frequently voiced gripe is that you can get this message even
114	if the pathname to an executable is fully qualified. But Perl can't
115	know that the executable in question isn't going to execute some other
116	program depending on the PATH.
117
118	It's also possible to get into trouble with other operations that don't
119	care whether they use tainted values. Make judicious use of the file
120	tests in dealing with any user-supplied filenames. When possible, do
121	opens and such after setting C<$E<gt> = $E<lt>>. (Remember group IDs,
122	too!) Perl doesn't prevent you from opening tainted filenames for reading,
123	so be careful what you print out. The tainting mechanism is intended to
124	prevent stupid mistakes, not to remove the need for thought.
125