|
|
- """
- SecureTranport support for urllib3 via ctypes.
-
- This makes platform-native TLS available to urllib3 users on macOS without the
- use of a compiler. This is an important feature because the Python Package
- Index is moving to become a TLSv1.2-or-higher server, and the default OpenSSL
- that ships with macOS is not capable of doing TLSv1.2. The only way to resolve
- this is to give macOS users an alternative solution to the problem, and that
- solution is to use SecureTransport.
-
- We use ctypes here because this solution must not require a compiler. That's
- because pip is not allowed to require a compiler either.
-
- This is not intended to be a seriously long-term solution to this problem.
- The hope is that PEP 543 will eventually solve this issue for us, at which
- point we can retire this contrib module. But in the short term, we need to
- solve the impending tire fire that is Python on Mac without this kind of
- contrib module. So...here we are.
-
- To use this module, simply import and inject it::
-
- import urllib3.contrib.securetransport
- urllib3.contrib.securetransport.inject_into_urllib3()
-
- Happy TLSing!
- """
- from __future__ import absolute_import
-
- import contextlib
- import ctypes
- import errno
- import os.path
- import shutil
- import socket
- import ssl
- import threading
- import weakref
-
- from .. import util
- from ._securetransport.bindings import (
- Security, SecurityConst, CoreFoundation
- )
- from ._securetransport.low_level import (
- _assert_no_error, _cert_array_from_pem, _temporary_keychain,
- _load_client_cert_chain
- )
-
- try: # Platform-specific: Python 2
- from socket import _fileobject
- except ImportError: # Platform-specific: Python 3
- _fileobject = None
- from ..packages.backports.makefile import backport_makefile
-
- __all__ = ['inject_into_urllib3', 'extract_from_urllib3']
-
- # SNI always works
- HAS_SNI = True
-
- orig_util_HAS_SNI = util.HAS_SNI
- orig_util_SSLContext = util.ssl_.SSLContext
-
- # This dictionary is used by the read callback to obtain a handle to the
- # calling wrapped socket. This is a pretty silly approach, but for now it'll
- # do. I feel like I should be able to smuggle a handle to the wrapped socket
- # directly in the SSLConnectionRef, but for now this approach will work I
- # guess.
- #
- # We need to lock around this structure for inserts, but we don't do it for
- # reads/writes in the callbacks. The reasoning here goes as follows:
- #
- # 1. It is not possible to call into the callbacks before the dictionary is
- # populated, so once in the callback the id must be in the dictionary.
- # 2. The callbacks don't mutate the dictionary, they only read from it, and
- # so cannot conflict with any of the insertions.
- #
- # This is good: if we had to lock in the callbacks we'd drastically slow down
- # the performance of this code.
- _connection_refs = weakref.WeakValueDictionary()
- _connection_ref_lock = threading.Lock()
-
- # Limit writes to 16kB. This is OpenSSL's limit, but we'll cargo-cult it over
- # for no better reason than we need *a* limit, and this one is right there.
- SSL_WRITE_BLOCKSIZE = 16384
-
- # This is our equivalent of util.ssl_.DEFAULT_CIPHERS, but expanded out to
- # individual cipher suites. We need to do this because this is how
- # SecureTransport wants them.
- CIPHER_SUITES = [
- SecurityConst.TLS_AES_256_GCM_SHA384,
- SecurityConst.TLS_CHACHA20_POLY1305_SHA256,
- SecurityConst.TLS_AES_128_GCM_SHA256,
- SecurityConst.TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384,
- SecurityConst.TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384,
- SecurityConst.TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256,
- SecurityConst.TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256,
- SecurityConst.TLS_DHE_DSS_WITH_AES_256_GCM_SHA384,
- SecurityConst.TLS_DHE_RSA_WITH_AES_256_GCM_SHA384,
- SecurityConst.TLS_DHE_DSS_WITH_AES_128_GCM_SHA256,
- SecurityConst.TLS_DHE_RSA_WITH_AES_128_GCM_SHA256,
- SecurityConst.TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA384,
- SecurityConst.TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA384,
- SecurityConst.TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA,
- SecurityConst.TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA,
- SecurityConst.TLS_DHE_RSA_WITH_AES_256_CBC_SHA256,
- SecurityConst.TLS_DHE_DSS_WITH_AES_256_CBC_SHA256,
- SecurityConst.TLS_DHE_RSA_WITH_AES_256_CBC_SHA,
- SecurityConst.TLS_DHE_DSS_WITH_AES_256_CBC_SHA,
- SecurityConst.TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256,
- SecurityConst.TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256,
- SecurityConst.TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA,
- SecurityConst.TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA,
- SecurityConst.TLS_DHE_RSA_WITH_AES_128_CBC_SHA256,
- SecurityConst.TLS_DHE_DSS_WITH_AES_128_CBC_SHA256,
- SecurityConst.TLS_DHE_RSA_WITH_AES_128_CBC_SHA,
- SecurityConst.TLS_DHE_DSS_WITH_AES_128_CBC_SHA,
- SecurityConst.TLS_RSA_WITH_AES_256_GCM_SHA384,
- SecurityConst.TLS_RSA_WITH_AES_128_GCM_SHA256,
- SecurityConst.TLS_RSA_WITH_AES_256_CBC_SHA256,
- SecurityConst.TLS_RSA_WITH_AES_128_CBC_SHA256,
- SecurityConst.TLS_RSA_WITH_AES_256_CBC_SHA,
- SecurityConst.TLS_RSA_WITH_AES_128_CBC_SHA,
- ]
-
- # Basically this is simple: for PROTOCOL_SSLv23 we turn it into a low of
- # TLSv1 and a high of TLSv1.2. For everything else, we pin to that version.
- _protocol_to_min_max = {
- ssl.PROTOCOL_SSLv23: (SecurityConst.kTLSProtocol1, SecurityConst.kTLSProtocol12),
- }
-
- if hasattr(ssl, "PROTOCOL_SSLv2"):
- _protocol_to_min_max[ssl.PROTOCOL_SSLv2] = (
- SecurityConst.kSSLProtocol2, SecurityConst.kSSLProtocol2
- )
- if hasattr(ssl, "PROTOCOL_SSLv3"):
- _protocol_to_min_max[ssl.PROTOCOL_SSLv3] = (
- SecurityConst.kSSLProtocol3, SecurityConst.kSSLProtocol3
- )
- if hasattr(ssl, "PROTOCOL_TLSv1"):
- _protocol_to_min_max[ssl.PROTOCOL_TLSv1] = (
- SecurityConst.kTLSProtocol1, SecurityConst.kTLSProtocol1
- )
- if hasattr(ssl, "PROTOCOL_TLSv1_1"):
- _protocol_to_min_max[ssl.PROTOCOL_TLSv1_1] = (
- SecurityConst.kTLSProtocol11, SecurityConst.kTLSProtocol11
- )
- if hasattr(ssl, "PROTOCOL_TLSv1_2"):
- _protocol_to_min_max[ssl.PROTOCOL_TLSv1_2] = (
- SecurityConst.kTLSProtocol12, SecurityConst.kTLSProtocol12
- )
- if hasattr(ssl, "PROTOCOL_TLS"):
- _protocol_to_min_max[ssl.PROTOCOL_TLS] = _protocol_to_min_max[ssl.PROTOCOL_SSLv23]
-
-
- def inject_into_urllib3():
- """
- Monkey-patch urllib3 with SecureTransport-backed SSL-support.
- """
- util.ssl_.SSLContext = SecureTransportContext
- util.HAS_SNI = HAS_SNI
- util.ssl_.HAS_SNI = HAS_SNI
- util.IS_SECURETRANSPORT = True
- util.ssl_.IS_SECURETRANSPORT = True
-
-
- def extract_from_urllib3():
- """
- Undo monkey-patching by :func:`inject_into_urllib3`.
- """
- util.ssl_.SSLContext = orig_util_SSLContext
- util.HAS_SNI = orig_util_HAS_SNI
- util.ssl_.HAS_SNI = orig_util_HAS_SNI
- util.IS_SECURETRANSPORT = False
- util.ssl_.IS_SECURETRANSPORT = False
-
-
- def _read_callback(connection_id, data_buffer, data_length_pointer):
- """
- SecureTransport read callback. This is called by ST to request that data
- be returned from the socket.
- """
- wrapped_socket = None
- try:
- wrapped_socket = _connection_refs.get(connection_id)
- if wrapped_socket is None:
- return SecurityConst.errSSLInternal
- base_socket = wrapped_socket.socket
-
- requested_length = data_length_pointer[0]
-
- timeout = wrapped_socket.gettimeout()
- error = None
- read_count = 0
-
- try:
- while read_count < requested_length:
- if timeout is None or timeout >= 0:
- if not util.wait_for_read(base_socket, timeout):
- raise socket.error(errno.EAGAIN, 'timed out')
-
- remaining = requested_length - read_count
- buffer = (ctypes.c_char * remaining).from_address(
- data_buffer + read_count
- )
- chunk_size = base_socket.recv_into(buffer, remaining)
- read_count += chunk_size
- if not chunk_size:
- if not read_count:
- return SecurityConst.errSSLClosedGraceful
- break
- except (socket.error) as e:
- error = e.errno
-
- if error is not None and error != errno.EAGAIN:
- data_length_pointer[0] = read_count
- if error == errno.ECONNRESET or error == errno.EPIPE:
- return SecurityConst.errSSLClosedAbort
- raise
-
- data_length_pointer[0] = read_count
-
- if read_count != requested_length:
- return SecurityConst.errSSLWouldBlock
-
- return 0
- except Exception as e:
- if wrapped_socket is not None:
- wrapped_socket._exception = e
- return SecurityConst.errSSLInternal
-
-
- def _write_callback(connection_id, data_buffer, data_length_pointer):
- """
- SecureTransport write callback. This is called by ST to request that data
- actually be sent on the network.
- """
- wrapped_socket = None
- try:
- wrapped_socket = _connection_refs.get(connection_id)
- if wrapped_socket is None:
- return SecurityConst.errSSLInternal
- base_socket = wrapped_socket.socket
-
- bytes_to_write = data_length_pointer[0]
- data = ctypes.string_at(data_buffer, bytes_to_write)
-
- timeout = wrapped_socket.gettimeout()
- error = None
- sent = 0
-
- try:
- while sent < bytes_to_write:
- if timeout is None or timeout >= 0:
- if not util.wait_for_write(base_socket, timeout):
- raise socket.error(errno.EAGAIN, 'timed out')
- chunk_sent = base_socket.send(data)
- sent += chunk_sent
-
- # This has some needless copying here, but I'm not sure there's
- # much value in optimising this data path.
- data = data[chunk_sent:]
- except (socket.error) as e:
- error = e.errno
-
- if error is not None and error != errno.EAGAIN:
- data_length_pointer[0] = sent
- if error == errno.ECONNRESET or error == errno.EPIPE:
- return SecurityConst.errSSLClosedAbort
- raise
-
- data_length_pointer[0] = sent
-
- if sent != bytes_to_write:
- return SecurityConst.errSSLWouldBlock
-
- return 0
- except Exception as e:
- if wrapped_socket is not None:
- wrapped_socket._exception = e
- return SecurityConst.errSSLInternal
-
-
- # We need to keep these two objects references alive: if they get GC'd while
- # in use then SecureTransport could attempt to call a function that is in freed
- # memory. That would be...uh...bad. Yeah, that's the word. Bad.
- _read_callback_pointer = Security.SSLReadFunc(_read_callback)
- _write_callback_pointer = Security.SSLWriteFunc(_write_callback)
-
-
- class WrappedSocket(object):
- """
- API-compatibility wrapper for Python's OpenSSL wrapped socket object.
-
- Note: _makefile_refs, _drop(), and _reuse() are needed for the garbage
- collector of PyPy.
- """
- def __init__(self, socket):
- self.socket = socket
- self.context = None
- self._makefile_refs = 0
- self._closed = False
- self._exception = None
- self._keychain = None
- self._keychain_dir = None
- self._client_cert_chain = None
-
- # We save off the previously-configured timeout and then set it to
- # zero. This is done because we use select and friends to handle the
- # timeouts, but if we leave the timeout set on the lower socket then
- # Python will "kindly" call select on that socket again for us. Avoid
- # that by forcing the timeout to zero.
- self._timeout = self.socket.gettimeout()
- self.socket.settimeout(0)
-
- @contextlib.contextmanager
- def _raise_on_error(self):
- """
- A context manager that can be used to wrap calls that do I/O from
- SecureTransport. If any of the I/O callbacks hit an exception, this
- context manager will correctly propagate the exception after the fact.
- This avoids silently swallowing those exceptions.
-
- It also correctly forces the socket closed.
- """
- self._exception = None
-
- # We explicitly don't catch around this yield because in the unlikely
- # event that an exception was hit in the block we don't want to swallow
- # it.
- yield
- if self._exception is not None:
- exception, self._exception = self._exception, None
- self.close()
- raise exception
-
- def _set_ciphers(self):
- """
- Sets up the allowed ciphers. By default this matches the set in
- util.ssl_.DEFAULT_CIPHERS, at least as supported by macOS. This is done
- custom and doesn't allow changing at this time, mostly because parsing
- OpenSSL cipher strings is going to be a freaking nightmare.
- """
- ciphers = (Security.SSLCipherSuite * len(CIPHER_SUITES))(*CIPHER_SUITES)
- result = Security.SSLSetEnabledCiphers(
- self.context, ciphers, len(CIPHER_SUITES)
- )
- _assert_no_error(result)
-
- def _custom_validate(self, verify, trust_bundle):
- """
- Called when we have set custom validation. We do this in two cases:
- first, when cert validation is entirely disabled; and second, when
- using a custom trust DB.
- """
- # If we disabled cert validation, just say: cool.
- if not verify:
- return
-
- # We want data in memory, so load it up.
- if os.path.isfile(trust_bundle):
- with open(trust_bundle, 'rb') as f:
- trust_bundle = f.read()
-
- cert_array = None
- trust = Security.SecTrustRef()
-
- try:
- # Get a CFArray that contains the certs we want.
- cert_array = _cert_array_from_pem(trust_bundle)
-
- # Ok, now the hard part. We want to get the SecTrustRef that ST has
- # created for this connection, shove our CAs into it, tell ST to
- # ignore everything else it knows, and then ask if it can build a
- # chain. This is a buuuunch of code.
- result = Security.SSLCopyPeerTrust(
- self.context, ctypes.byref(trust)
- )
- _assert_no_error(result)
- if not trust:
- raise ssl.SSLError("Failed to copy trust reference")
-
- result = Security.SecTrustSetAnchorCertificates(trust, cert_array)
- _assert_no_error(result)
-
- result = Security.SecTrustSetAnchorCertificatesOnly(trust, True)
- _assert_no_error(result)
-
- trust_result = Security.SecTrustResultType()
- result = Security.SecTrustEvaluate(
- trust, ctypes.byref(trust_result)
- )
- _assert_no_error(result)
- finally:
- if trust:
- CoreFoundation.CFRelease(trust)
-
- if cert_array is not None:
- CoreFoundation.CFRelease(cert_array)
-
- # Ok, now we can look at what the result was.
- successes = (
- SecurityConst.kSecTrustResultUnspecified,
- SecurityConst.kSecTrustResultProceed
- )
- if trust_result.value not in successes:
- raise ssl.SSLError(
- "certificate verify failed, error code: %d" %
- trust_result.value
- )
-
- def handshake(self,
- server_hostname,
- verify,
- trust_bundle,
- min_version,
- max_version,
- client_cert,
- client_key,
- client_key_passphrase):
- """
- Actually performs the TLS handshake. This is run automatically by
- wrapped socket, and shouldn't be needed in user code.
- """
- # First, we do the initial bits of connection setup. We need to create
- # a context, set its I/O funcs, and set the connection reference.
- self.context = Security.SSLCreateContext(
- None, SecurityConst.kSSLClientSide, SecurityConst.kSSLStreamType
- )
- result = Security.SSLSetIOFuncs(
- self.context, _read_callback_pointer, _write_callback_pointer
- )
- _assert_no_error(result)
-
- # Here we need to compute the handle to use. We do this by taking the
- # id of self modulo 2**31 - 1. If this is already in the dictionary, we
- # just keep incrementing by one until we find a free space.
- with _connection_ref_lock:
- handle = id(self) % 2147483647
- while handle in _connection_refs:
- handle = (handle + 1) % 2147483647
- _connection_refs[handle] = self
-
- result = Security.SSLSetConnection(self.context, handle)
- _assert_no_error(result)
-
- # If we have a server hostname, we should set that too.
- if server_hostname:
- if not isinstance(server_hostname, bytes):
- server_hostname = server_hostname.encode('utf-8')
-
- result = Security.SSLSetPeerDomainName(
- self.context, server_hostname, len(server_hostname)
- )
- _assert_no_error(result)
-
- # Setup the ciphers.
- self._set_ciphers()
-
- # Set the minimum and maximum TLS versions.
- result = Security.SSLSetProtocolVersionMin(self.context, min_version)
- _assert_no_error(result)
- result = Security.SSLSetProtocolVersionMax(self.context, max_version)
- _assert_no_error(result)
-
- # If there's a trust DB, we need to use it. We do that by telling
- # SecureTransport to break on server auth. We also do that if we don't
- # want to validate the certs at all: we just won't actually do any
- # authing in that case.
- if not verify or trust_bundle is not None:
- result = Security.SSLSetSessionOption(
- self.context,
- SecurityConst.kSSLSessionOptionBreakOnServerAuth,
- True
- )
- _assert_no_error(result)
-
- # If there's a client cert, we need to use it.
- if client_cert:
- self._keychain, self._keychain_dir = _temporary_keychain()
- self._client_cert_chain = _load_client_cert_chain(
- self._keychain, client_cert, client_key
- )
- result = Security.SSLSetCertificate(
- self.context, self._client_cert_chain
- )
- _assert_no_error(result)
-
- while True:
- with self._raise_on_error():
- result = Security.SSLHandshake(self.context)
-
- if result == SecurityConst.errSSLWouldBlock:
- raise socket.timeout("handshake timed out")
- elif result == SecurityConst.errSSLServerAuthCompleted:
- self._custom_validate(verify, trust_bundle)
- continue
- else:
- _assert_no_error(result)
- break
-
- def fileno(self):
- return self.socket.fileno()
-
- # Copy-pasted from Python 3.5 source code
- def _decref_socketios(self):
- if self._makefile_refs > 0:
- self._makefile_refs -= 1
- if self._closed:
- self.close()
-
- def recv(self, bufsiz):
- buffer = ctypes.create_string_buffer(bufsiz)
- bytes_read = self.recv_into(buffer, bufsiz)
- data = buffer[:bytes_read]
- return data
-
- def recv_into(self, buffer, nbytes=None):
- # Read short on EOF.
- if self._closed:
- return 0
-
- if nbytes is None:
- nbytes = len(buffer)
-
- buffer = (ctypes.c_char * nbytes).from_buffer(buffer)
- processed_bytes = ctypes.c_size_t(0)
-
- with self._raise_on_error():
- result = Security.SSLRead(
- self.context, buffer, nbytes, ctypes.byref(processed_bytes)
- )
-
- # There are some result codes that we want to treat as "not always
- # errors". Specifically, those are errSSLWouldBlock,
- # errSSLClosedGraceful, and errSSLClosedNoNotify.
- if (result == SecurityConst.errSSLWouldBlock):
- # If we didn't process any bytes, then this was just a time out.
- # However, we can get errSSLWouldBlock in situations when we *did*
- # read some data, and in those cases we should just read "short"
- # and return.
- if processed_bytes.value == 0:
- # Timed out, no data read.
- raise socket.timeout("recv timed out")
- elif result in (SecurityConst.errSSLClosedGraceful, SecurityConst.errSSLClosedNoNotify):
- # The remote peer has closed this connection. We should do so as
- # well. Note that we don't actually return here because in
- # principle this could actually be fired along with return data.
- # It's unlikely though.
- self.close()
- else:
- _assert_no_error(result)
-
- # Ok, we read and probably succeeded. We should return whatever data
- # was actually read.
- return processed_bytes.value
-
- def settimeout(self, timeout):
- self._timeout = timeout
-
- def gettimeout(self):
- return self._timeout
-
- def send(self, data):
- processed_bytes = ctypes.c_size_t(0)
-
- with self._raise_on_error():
- result = Security.SSLWrite(
- self.context, data, len(data), ctypes.byref(processed_bytes)
- )
-
- if result == SecurityConst.errSSLWouldBlock and processed_bytes.value == 0:
- # Timed out
- raise socket.timeout("send timed out")
- else:
- _assert_no_error(result)
-
- # We sent, and probably succeeded. Tell them how much we sent.
- return processed_bytes.value
-
- def sendall(self, data):
- total_sent = 0
- while total_sent < len(data):
- sent = self.send(data[total_sent:total_sent + SSL_WRITE_BLOCKSIZE])
- total_sent += sent
-
- def shutdown(self):
- with self._raise_on_error():
- Security.SSLClose(self.context)
-
- def close(self):
- # TODO: should I do clean shutdown here? Do I have to?
- if self._makefile_refs < 1:
- self._closed = True
- if self.context:
- CoreFoundation.CFRelease(self.context)
- self.context = None
- if self._client_cert_chain:
- CoreFoundation.CFRelease(self._client_cert_chain)
- self._client_cert_chain = None
- if self._keychain:
- Security.SecKeychainDelete(self._keychain)
- CoreFoundation.CFRelease(self._keychain)
- shutil.rmtree(self._keychain_dir)
- self._keychain = self._keychain_dir = None
- return self.socket.close()
- else:
- self._makefile_refs -= 1
-
- def getpeercert(self, binary_form=False):
- # Urgh, annoying.
- #
- # Here's how we do this:
- #
- # 1. Call SSLCopyPeerTrust to get hold of the trust object for this
- # connection.
- # 2. Call SecTrustGetCertificateAtIndex for index 0 to get the leaf.
- # 3. To get the CN, call SecCertificateCopyCommonName and process that
- # string so that it's of the appropriate type.
- # 4. To get the SAN, we need to do something a bit more complex:
- # a. Call SecCertificateCopyValues to get the data, requesting
- # kSecOIDSubjectAltName.
- # b. Mess about with this dictionary to try to get the SANs out.
- #
- # This is gross. Really gross. It's going to be a few hundred LoC extra
- # just to repeat something that SecureTransport can *already do*. So my
- # operating assumption at this time is that what we want to do is
- # instead to just flag to urllib3 that it shouldn't do its own hostname
- # validation when using SecureTransport.
- if not binary_form:
- raise ValueError(
- "SecureTransport only supports dumping binary certs"
- )
- trust = Security.SecTrustRef()
- certdata = None
- der_bytes = None
-
- try:
- # Grab the trust store.
- result = Security.SSLCopyPeerTrust(
- self.context, ctypes.byref(trust)
- )
- _assert_no_error(result)
- if not trust:
- # Probably we haven't done the handshake yet. No biggie.
- return None
-
- cert_count = Security.SecTrustGetCertificateCount(trust)
- if not cert_count:
- # Also a case that might happen if we haven't handshaked.
- # Handshook? Handshaken?
- return None
-
- leaf = Security.SecTrustGetCertificateAtIndex(trust, 0)
- assert leaf
-
- # Ok, now we want the DER bytes.
- certdata = Security.SecCertificateCopyData(leaf)
- assert certdata
-
- data_length = CoreFoundation.CFDataGetLength(certdata)
- data_buffer = CoreFoundation.CFDataGetBytePtr(certdata)
- der_bytes = ctypes.string_at(data_buffer, data_length)
- finally:
- if certdata:
- CoreFoundation.CFRelease(certdata)
- if trust:
- CoreFoundation.CFRelease(trust)
-
- return der_bytes
-
- def _reuse(self):
- self._makefile_refs += 1
-
- def _drop(self):
- if self._makefile_refs < 1:
- self.close()
- else:
- self._makefile_refs -= 1
-
-
- if _fileobject: # Platform-specific: Python 2
- def makefile(self, mode, bufsize=-1):
- self._makefile_refs += 1
- return _fileobject(self, mode, bufsize, close=True)
- else: # Platform-specific: Python 3
- def makefile(self, mode="r", buffering=None, *args, **kwargs):
- # We disable buffering with SecureTransport because it conflicts with
- # the buffering that ST does internally (see issue #1153 for more).
- buffering = 0
- return backport_makefile(self, mode, buffering, *args, **kwargs)
-
- WrappedSocket.makefile = makefile
-
-
- class SecureTransportContext(object):
- """
- I am a wrapper class for the SecureTransport library, to translate the
- interface of the standard library ``SSLContext`` object to calls into
- SecureTransport.
- """
- def __init__(self, protocol):
- self._min_version, self._max_version = _protocol_to_min_max[protocol]
- self._options = 0
- self._verify = False
- self._trust_bundle = None
- self._client_cert = None
- self._client_key = None
- self._client_key_passphrase = None
-
- @property
- def check_hostname(self):
- """
- SecureTransport cannot have its hostname checking disabled. For more,
- see the comment on getpeercert() in this file.
- """
- return True
-
- @check_hostname.setter
- def check_hostname(self, value):
- """
- SecureTransport cannot have its hostname checking disabled. For more,
- see the comment on getpeercert() in this file.
- """
- pass
-
- @property
- def options(self):
- # TODO: Well, crap.
- #
- # So this is the bit of the code that is the most likely to cause us
- # trouble. Essentially we need to enumerate all of the SSL options that
- # users might want to use and try to see if we can sensibly translate
- # them, or whether we should just ignore them.
- return self._options
-
- @options.setter
- def options(self, value):
- # TODO: Update in line with above.
- self._options = value
-
- @property
- def verify_mode(self):
- return ssl.CERT_REQUIRED if self._verify else ssl.CERT_NONE
-
- @verify_mode.setter
- def verify_mode(self, value):
- self._verify = True if value == ssl.CERT_REQUIRED else False
-
- def set_default_verify_paths(self):
- # So, this has to do something a bit weird. Specifically, what it does
- # is nothing.
- #
- # This means that, if we had previously had load_verify_locations
- # called, this does not undo that. We need to do that because it turns
- # out that the rest of the urllib3 code will attempt to load the
- # default verify paths if it hasn't been told about any paths, even if
- # the context itself was sometime earlier. We resolve that by just
- # ignoring it.
- pass
-
- def load_default_certs(self):
- return self.set_default_verify_paths()
-
- def set_ciphers(self, ciphers):
- # For now, we just require the default cipher string.
- if ciphers != util.ssl_.DEFAULT_CIPHERS:
- raise ValueError(
- "SecureTransport doesn't support custom cipher strings"
- )
-
- def load_verify_locations(self, cafile=None, capath=None, cadata=None):
- # OK, we only really support cadata and cafile.
- if capath is not None:
- raise ValueError(
- "SecureTransport does not support cert directories"
- )
-
- self._trust_bundle = cafile or cadata
-
- def load_cert_chain(self, certfile, keyfile=None, password=None):
- self._client_cert = certfile
- self._client_key = keyfile
- self._client_cert_passphrase = password
-
- def wrap_socket(self, sock, server_side=False,
- do_handshake_on_connect=True, suppress_ragged_eofs=True,
- server_hostname=None):
- # So, what do we do here? Firstly, we assert some properties. This is a
- # stripped down shim, so there is some functionality we don't support.
- # See PEP 543 for the real deal.
- assert not server_side
- assert do_handshake_on_connect
- assert suppress_ragged_eofs
-
- # Ok, we're good to go. Now we want to create the wrapped socket object
- # and store it in the appropriate place.
- wrapped_socket = WrappedSocket(sock)
-
- # Now we can handshake
- wrapped_socket.handshake(
- server_hostname, self._verify, self._trust_bundle,
- self._min_version, self._max_version, self._client_cert,
- self._client_key, self._client_key_passphrase
- )
- return wrapped_socket
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