use Safe; $compartment = new Safe; $compartment->permit(qw(time sort :browse)); $result = $compartment->reval($unsafe_code);
Code which is compiled outside the compartment can choose to place variables into (or share variables with) the compartment's namespace and only that data will be visible to code evaluated in the compartment.
By default, the only variables shared with compartments are the ``underscore'' variables $_ and @_ (and, technically, the less frequently used %_, the _ filehandle and so on). This is because otherwise perl operators which default to $_ will not work and neither will the assignment of arguments to @_ on subroutine entry.
The default operator mask for a newly created compartment is the ':default' optag.
It is important that you read the Opcode module documentation for more information, especially for detailed definitions of opnames, optags and opsets.
Since it is only at the compilation stage that the operator mask applies, controlled access to potentially unsafe operations can be achieved by having a handle to a wrapper subroutine (written outside the compartment) placed into the compartment. For example,
$cpt = new Safe; sub wrapper { # vet arguments and perform potentially unsafe operations } $cpt->share('&wrapper');
Bugs in the perl interpreter that could be abused to bypass Safe restrictions are not treated as vulnerabilities. See perlsecpolicy for additional information.
The authors make no warranty, implied or otherwise, about the suitability of this software for safety or security purposes.
The authors shall not in any case be liable for special, incidental, consequential, indirect or other similar damages arising from the use of this software.
Your mileage will vary. If in any doubt do not use it.
$cpt = new Safe;
Optional argument is (NAMESPACE), where NAMESPACE is the root namespace to use for the compartment (defaults to ``Safe::Root0'', incremented for each new compartment).
Note that version 1.00 of the Safe module supported a second optional parameter, MASK. That functionality has been withdrawn pending deeper consideration. Use the permit and deny methods described below.
The following methods can then be used on the compartment object returned by the above constructor. The object argument is implicit in each case.
You can list opcodes by names, or use a tag name; see ``Predefined Opcode Tags'' in Opcode.
Each NAME must be the name of a non-lexical variable, typically with the leading type identifier included. A bareword is treated as a function name.
Examples of legal names are '$foo' for a scalar, '@foo' for an array, '%foo' for a hash, '&foo' or 'foo' for a subroutine and '*foo' for a glob (i.e. all symbol table entries associated with ``foo'', including scalar, array, hash, sub and filehandle).
Each NAME is assumed to be in the calling package. See share_from for an alternative method (which "share" uses).
$safe->share_from('main', [ '$foo', '%bar', 'func' ]);
Names can include package names, which are relative to the specified PACKAGE. So these two calls have the same effect:
$safe->share_from('Scalar::Util', [ 'reftype' ]); $safe->share_from('main', [ 'Scalar::Util::reftype' ]);
${$cpt->varglob('foo')} = "Hello world";
has the same effect as:
$cpt = new Safe 'Root'; $Root::foo = "Hello world";
but avoids the need to know $cpt's package name.
The code can only see the compartment's namespace (as returned by the root method). The compartment's root package appears to be the "main::" package to the code inside the compartment.
Any attempt by the code in STRING to use an operator which is not permitted by the compartment will cause an error (at run-time of the main program but at compile-time for the code in STRING). The error is of the form ``'%s' trapped by operation mask...''.
If an operation is trapped in this way, then the code in STRING will not be executed. If such a trapped operation occurs or any other compile-time or return error, then $@ is set to the error message, just as with an eval().
If there is no error, then the method returns the value of the last expression evaluated, or a return statement may be used, just as with subroutines and eval(). The context (list or scalar) is determined by the caller as usual.
If the return value of reval() is (or contains) any code reference, those code references are wrapped to be themselves executed always in the compartment. See ``wrap_code_refs_within''.
The formerly undocumented STRICT argument sets strictness: if true 'use strict;' is used, otherwise it uses 'no strict;'. Note: if STRICT is omitted 'no strict;' is the default.
Some points to note:
If the entereval op is permitted then the code can use eval ``...'' to 'hide' code which might use denied ops. This is not a major problem since when the code tries to execute the eval it will fail because the opmask is still in effect. However this technique would allow clever, and possibly harmful, code to 'probe' the boundaries of what is possible.
Any string eval which is executed by code executing in a compartment, or by code called from code executing in a compartment, will be eval'd in the namespace of the compartment. This is potentially a serious problem.
Consider a function foo() in package pkg compiled outside a compartment but shared with it. Assume the compartment has a root package called 'Root'. If foo() contains an eval statement like eval '$foo = 1' then, normally, $pkg::foo will be set to 1. If foo() is called from the compartment (by whatever means) then instead of setting $pkg::foo, the eval will actually set $Root::pkg::foo.
This can easily be demonstrated by using a module, such as the Socket module, which uses eval ``...'' as part of an AUTOLOAD function. You can 'use' the module outside the compartment and share an (autoloaded) function with the compartment. If an autoload is triggered by code in the compartment, or by any code anywhere that is called by any means from the compartment, then the eval in the Socket module's AUTOLOAD function happens in the namespace of the compartment. Any variables created or used by the eval'd code are now under the control of the code in the compartment.
A similar effect applies to all runtime symbol lookups in code called from a compartment but not compiled within it.
See above documentation on the reval method for further details.
Note that this behaviour differs from version 1.00 of the Safe module where the root module could be used to change the namespace. That functionality has been withdrawn pending deeper consideration.
With no MASK argument present, it returns the current operator mask of the compartment.
With the MASK argument present, it sets the operator mask for the compartment (equivalent to calling the deny_only method).
Note that the opmask doesn't affect the already compiled code, it only affects any further compilation that the already compiled code may try to perform.
This is particularly useful when applied to code references returned from reval().
(It also provides a kind of workaround for RT#60374: ``Safe.pm sort {} bug with -Dusethreads''. See <https://rt.perl.org/rt3//Public/Bug/Display.html?id=60374> for much more detail.)
Setting up a signal handler will need to be carefully considered and controlled. What mask is in effect when a signal handler gets called? If a user can get an imported function to get an exception and call the user's signal handler, does that user's restricted mask get re-instated before the handler is called? Does an imported handler get called with its original mask or the user's one?
Reworked to use the Opcode module and other changes added by Tim Bunce.
Currently maintained by the Perl 5 Porters, <perl5-porters@perl.org>.