Doc/librestricted.tex - platform/external/python/cpython3 - Gitiles

 \chapter{Restricted Execution}

 In general, Python programs have complete access to the underlying
 operating system throug the various functions and classes, For
 example, a Python program can open any file for reading and writing by
 using the \code{open()} built-in function (provided the underlying OS
 gives you permission!).  This is exactly what you want for most
 applications.

 There exists a class of applications for which this ``openness'' is
 inappropriate.  Take Grail: a web browser that accepts ``applets'',
 snippets of Python code, from anywhere on the Internet for execution
 on the local system.  This can be used to improve the user interface
 of forms, for instance.  Since the originator of the code is unknown,
 it is obvious that it cannot be trusted with the full resources of the
 local machine.

 \emph{Restricted execution} is the basic framework in Python that allows
 for the segregation of trusted and untrusted code.  It is based on the
 notion that trusted Python code (a \emph{supervisor}) can create a
 ``padded cell' (or environment) with limited permissions, and run the
 untrusted code within this cell.  The untrusted code cannot break out
 of its cell, and can only interact with sensitive system resources
 through interfaces defined and managed by the trusted code.  The term
 ``restricted execution'' is favored over ``safe-Python''
 since true safety is hard to define, and is determined by the way the
 restricted environment is created.  Note that the restricted
 environments can be nested, with inner cells creating subcells of
 lesser, but never greater, privilege.

 An interesting aspect of Python's restricted execution model is that
 the interfaces presented to untrusted code usually have the same names
 as those presented to trusted code.  Therefore no special interfaces
 need to be learned to write code designed to run in a restricted
 environment.  And because the exact nature of the padded cell is
 determined by the supervisor, different restrictions can be imposed,
 depending on the application.  For example, it might be deemed
 ``safe'' for untrusted code to read any file within a specified
 directory, but never to write a file.  In this case, the supervisor
 may redefine the built-in
 \code{open()} function so that it raises an exception whenever the
 \var{mode} parameter is \code{'w'}.  It might also perform a
 \code{chroot()}-like operation on the \var{filename} parameter, such
 that root is always relative to some safe ``sandbox'' area of the
 filesystem.  In this case, the untrusted code would still see an
 built-in \code{open()} function in its environment, with the same
 calling interface.  The semantics would be identical too, with
 \code{IOError}s being raised when the supervisor determined that an
 unallowable parameter is being used.

 The Python run-time determines whether a particular code block is
 executing in restricted execution mode based on the identity of the
 \code{__builtins__} object in its global variables: if this is (the
 dictionary of) the standard \code{__builtin__} module, the code is
 deemed to be unrestricted, else it is deemed to be restricted.

 Python code executing in restricted mode faces a number of limitations
 that are designed to prevent it from escaping from the padded cell.
 For instance, the function object attribute \code{func_globals} and the
 class and instance object attribute \code{__dict__} are unavailable.

 Two modules provide the framework for setting up restricted execution
 environments:

 \begin{description}

 \item[rexec]
 --- Basic restricted execution framework.

 \item[Bastion]
 --- Providing restricted access to objects.

 \end{description}
	\chapter{Restricted Execution}

	In general, Python programs have complete access to the underlying
	operating system throug the various functions and classes, For
	example, a Python program can open any file for reading and writing by
	using the \code{open()} built-in function (provided the underlying OS
	gives you permission!). This is exactly what you want for most
	applications.

	There exists a class of applications for which this ``openness'' is
	inappropriate. Take Grail: a web browser that accepts ``applets'',
	snippets of Python code, from anywhere on the Internet for execution
	on the local system. This can be used to improve the user interface
	of forms, for instance. Since the originator of the code is unknown,
	it is obvious that it cannot be trusted with the full resources of the
	local machine.

	\emph{Restricted execution} is the basic framework in Python that allows
	for the segregation of trusted and untrusted code. It is based on the
	notion that trusted Python code (a \emph{supervisor}) can create a
	``padded cell' (or environment) with limited permissions, and run the
	untrusted code within this cell. The untrusted code cannot break out
	of its cell, and can only interact with sensitive system resources
	through interfaces defined and managed by the trusted code. The term
	``restricted execution'' is favored over ``safe-Python''
	since true safety is hard to define, and is determined by the way the
	restricted environment is created. Note that the restricted
	environments can be nested, with inner cells creating subcells of
	lesser, but never greater, privilege.

	An interesting aspect of Python's restricted execution model is that
	the interfaces presented to untrusted code usually have the same names
	as those presented to trusted code. Therefore no special interfaces
	need to be learned to write code designed to run in a restricted
	environment. And because the exact nature of the padded cell is
	determined by the supervisor, different restrictions can be imposed,
	depending on the application. For example, it might be deemed
	``safe'' for untrusted code to read any file within a specified
	directory, but never to write a file. In this case, the supervisor
	may redefine the built-in
	\code{open()} function so that it raises an exception whenever the
	\var{mode} parameter is \code{'w'}. It might also perform a
	\code{chroot()}-like operation on the \var{filename} parameter, such
	that root is always relative to some safe ``sandbox'' area of the
	filesystem. In this case, the untrusted code would still see an
	built-in \code{open()} function in its environment, with the same
	calling interface. The semantics would be identical too, with
	\code{IOError}s being raised when the supervisor determined that an
	unallowable parameter is being used.

	The Python run-time determines whether a particular code block is
	executing in restricted execution mode based on the identity of the
	\code{__builtins__} object in its global variables: if this is (the
	dictionary of) the standard \code{__builtin__} module, the code is
	deemed to be unrestricted, else it is deemed to be restricted.

	Python code executing in restricted mode faces a number of limitations
	that are designed to prevent it from escaping from the padded cell.
	For instance, the function object attribute \code{func_globals} and the
	class and instance object attribute \code{__dict__} are unavailable.

	Two modules provide the framework for setting up restricted execution
	environments:

	\begin{description}

	\item[rexec]
	--- Basic restricted execution framework.

	\item[Bastion]
	--- Providing restricted access to objects.

	\end{description}