""" The MIT License (MIT) Copyright (C) 2017-2021 Joe Testa (jtesta@positronsecurity.com) Copyright (C) 2017 Andris Raugulis (moo@arthepsy.eu) Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. """ import errno import os import select import socket import struct import sys # pylint: disable=unused-import from typing import Dict, List, Set, Sequence, Tuple, Iterable # noqa: F401 from typing import Callable, Optional, Union, Any # noqa: F401 from ssh_audit import exitcodes from ssh_audit.banner import Banner from ssh_audit.globals import SSH_HEADER from ssh_audit.outputbuffer import OutputBuffer from ssh_audit.protocol import Protocol from ssh_audit.readbuf import ReadBuf from ssh_audit.ssh1 import SSH1 from ssh_audit.ssh2_kex import SSH2_Kex from ssh_audit.ssh2_kexparty import SSH2_KexParty from ssh_audit.utils import Utils from ssh_audit.writebuf import WriteBuf class SSH_Socket(ReadBuf, WriteBuf): class InsufficientReadException(Exception): pass SM_BANNER_SENT = 1 def __init__(self, host: Optional[str], port: int, ip_version_preference: List[int] = [], timeout: Union[int, float] = 5, timeout_set: bool = False) -> None: # pylint: disable=dangerous-default-value super(SSH_Socket, self).__init__() self.__sock: Optional[socket.socket] = None self.__sock_map: Dict[int, socket.socket] = {} self.__block_size = 8 self.__state = 0 self.__header: List[str] = [] self.__banner: Optional[Banner] = None if host is None: raise ValueError('undefined host') nport = Utils.parse_int(port) if nport < 1 or nport > 65535: raise ValueError('invalid port: {}'.format(port)) self.__host = host self.__port = nport self.__ip_version_preference = ip_version_preference # Holds only 5 possible values: [] (no preference), [4] (use IPv4 only), [6] (use IPv6 only), [46] (use both IPv4 and IPv6, but prioritize v4), and [64] (use both IPv4 and IPv6, but prioritize v6). self.__timeout = timeout self.__timeout_set = timeout_set self.client_host: Optional[str] = None self.client_port = None def _resolve(self) -> Iterable[Tuple[int, Tuple[Any, ...]]]: # If __ip_version_preference has only one entry, then it means that ONLY that IP version should be used. if len(self.__ip_version_preference) == 1: family = socket.AF_INET if self.__ip_version_preference[0] == 4 else socket.AF_INET6 else: family = socket.AF_UNSPEC try: stype = socket.SOCK_STREAM r = socket.getaddrinfo(self.__host, self.__port, family, stype) # If the user has a preference for using IPv4 over IPv6 (or vice-versa), then sort the list returned by getaddrinfo() so that the preferred address type comes first. if len(self.__ip_version_preference) == 2: r = sorted(r, key=lambda x: x[0], reverse=(self.__ip_version_preference[0] == 6)) for af, socktype, _proto, _canonname, addr in r: if socktype == socket.SOCK_STREAM: yield af, addr except socket.error as e: OutputBuffer().fail('[exception] {}'.format(e)).write() sys.exit(exitcodes.CONNECTION_ERROR) # Listens on a server socket and accepts one connection (used for # auditing client connections). def listen_and_accept(self) -> None: try: # Socket to listen on all IPv4 addresses. s = socket.socket(socket.AF_INET, socket.SOCK_STREAM) s.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) s.bind(('0.0.0.0', self.__port)) s.listen() self.__sock_map[s.fileno()] = s except Exception: print("Warning: failed to listen on any IPv4 interfaces.") try: # Socket to listen on all IPv6 addresses. s = socket.socket(socket.AF_INET6, socket.SOCK_STREAM) s.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) s.setsockopt(socket.IPPROTO_IPV6, socket.IPV6_V6ONLY, 1) s.bind(('::', self.__port)) s.listen() self.__sock_map[s.fileno()] = s except Exception: print("Warning: failed to listen on any IPv6 interfaces.") # If we failed to listen on any interfaces, terminate. if len(self.__sock_map.keys()) == 0: print("Error: failed to listen on any IPv4 and IPv6 interfaces!") sys.exit(exitcodes.CONNECTION_ERROR) # Wait for an incoming connection. If a timeout was explicitly # set by the user, terminate when it elapses. fds = None time_elapsed = 0.0 interval = 1.0 while True: # Wait for a connection on either socket. fds = select.select(self.__sock_map.keys(), [], [], interval) time_elapsed += interval # We have incoming data on at least one of the sockets. if len(fds[0]) > 0: break if self.__timeout_set and time_elapsed >= self.__timeout: print("Timeout elapsed. Terminating...") sys.exit(exitcodes.CONNECTION_ERROR) # Accept the connection. c, addr = self.__sock_map[fds[0][0]].accept() self.client_host = addr[0] self.client_port = addr[1] c.settimeout(self.__timeout) self.__sock = c def connect(self, out: 'OutputBuffer') -> Optional[str]: '''Returns None on success, or an error string.''' err = None for af, addr in self._resolve(): s = None try: s = socket.socket(af, socket.SOCK_STREAM) s.settimeout(self.__timeout) out.d(("Connecting to %s:%d..." % ('[%s]' % addr[0] if Utils.is_ipv6_address(addr[0]) else addr[0], addr[1])), write_now=True) s.connect(addr) self.__sock = s return None except socket.error as e: err = e self._close_socket(s) if err is None: errm = 'host {} has no DNS records'.format(self.__host) else: errt = (self.__host, self.__port, err) errm = 'cannot connect to {} port {}: {}'.format(*errt) return '[exception] {}'.format(errm) def get_banner(self, out: 'OutputBuffer', sshv: int = 2) -> Tuple[Optional['Banner'], List[str], Optional[str]]: out.d('Getting banner...', write_now=True) if self.__sock is None: return self.__banner, self.__header, 'not connected' if self.__banner is not None: return self.__banner, self.__header, None banner = SSH_HEADER.format('1.5' if sshv == 1 else '2.0') if self.__state < self.SM_BANNER_SENT: self.send_banner(banner) s = 0 e = None while s >= 0: s, e = self.recv() if s < 0: continue while self.unread_len > 0: line = self.read_line() if len(line.strip()) == 0: continue self.__banner = Banner.parse(line) if self.__banner is not None: return self.__banner, self.__header, None self.__header.append(line) return self.__banner, self.__header, e def recv(self, size: int = 2048) -> Tuple[int, Optional[str]]: if self.__sock is None: return -1, 'not connected' try: data = self.__sock.recv(size) except socket.timeout: return -1, 'timed out' except socket.error as e: if e.args[0] in (errno.EAGAIN, errno.EWOULDBLOCK): return 0, 'retry' return -1, str(e.args[-1]) if len(data) == 0: return -1, None pos = self._buf.tell() self._buf.seek(0, 2) self._buf.write(data) self._len += len(data) self._buf.seek(pos, 0) return len(data), None def send(self, data: bytes) -> Tuple[int, Optional[str]]: if self.__sock is None: return -1, 'not connected' try: self.__sock.send(data) return 0, None except socket.error as e: return -1, str(e.args[-1]) # Send a KEXINIT with the lists of key exchanges, hostkeys, ciphers, MACs, compressions, and languages that we "support". def send_kexinit(self, out: 'OutputBuffer', key_exchanges: List[str] = ['curve25519-sha256', 'curve25519-sha256@libssh.org', 'ecdh-sha2-nistp256', 'ecdh-sha2-nistp384', 'ecdh-sha2-nistp521', 'diffie-hellman-group-exchange-sha256', 'diffie-hellman-group16-sha512', 'diffie-hellman-group18-sha512', 'diffie-hellman-group14-sha256'], hostkeys: List[str] = ['rsa-sha2-512', 'rsa-sha2-256', 'ssh-rsa', 'ecdsa-sha2-nistp256', 'ssh-ed25519'], ciphers: List[str] = ['chacha20-poly1305@openssh.com', 'aes128-ctr', 'aes192-ctr', 'aes256-ctr', 'aes128-gcm@openssh.com', 'aes256-gcm@openssh.com'], macs: List[str] = ['umac-64-etm@openssh.com', 'umac-128-etm@openssh.com', 'hmac-sha2-256-etm@openssh.com', 'hmac-sha2-512-etm@openssh.com', 'hmac-sha1-etm@openssh.com', 'umac-64@openssh.com', 'umac-128@openssh.com', 'hmac-sha2-256', 'hmac-sha2-512', 'hmac-sha1'], compressions: List[str] = ['none', 'zlib@openssh.com'], languages: List[str] = ['']) -> None: # pylint: disable=dangerous-default-value '''Sends the list of supported host keys, key exchanges, ciphers, and MACs. Emulates OpenSSH v8.2.''' out.d('KEX initialisation...', write_now=True) kexparty = SSH2_KexParty(ciphers, macs, compressions, languages) kex = SSH2_Kex(os.urandom(16), key_exchanges, hostkeys, kexparty, kexparty, False, 0) self.write_byte(Protocol.MSG_KEXINIT) kex.write(self) self.send_packet() def send_banner(self, banner: str) -> None: self.send(banner.encode() + b'\r\n') if self.__state < self.SM_BANNER_SENT: self.__state = self.SM_BANNER_SENT def ensure_read(self, size: int) -> None: while self.unread_len < size: s, e = self.recv() if s < 0: raise SSH_Socket.InsufficientReadException(e) def read_packet(self, sshv: int = 2) -> Tuple[int, bytes]: try: header = WriteBuf() self.ensure_read(4) packet_length = self.read_int() header.write_int(packet_length) # XXX: validate length if sshv == 1: padding_length = 8 - packet_length % 8 self.ensure_read(padding_length) padding = self.read(padding_length) header.write(padding) payload_length = packet_length check_size = padding_length + payload_length else: self.ensure_read(1) padding_length = self.read_byte() header.write_byte(padding_length) payload_length = packet_length - padding_length - 1 check_size = 4 + 1 + payload_length + padding_length if check_size % self.__block_size != 0: OutputBuffer().fail('[exception] invalid ssh packet (block size)').write() sys.exit(exitcodes.CONNECTION_ERROR) self.ensure_read(payload_length) if sshv == 1: payload = self.read(payload_length - 4) header.write(payload) crc = self.read_int() header.write_int(crc) else: payload = self.read(payload_length) header.write(payload) packet_type = ord(payload[0:1]) if sshv == 1: rcrc = SSH1.crc32(padding + payload) if crc != rcrc: OutputBuffer().fail('[exception] packet checksum CRC32 mismatch.').write() sys.exit(exitcodes.CONNECTION_ERROR) else: self.ensure_read(padding_length) padding = self.read(padding_length) payload = payload[1:] return packet_type, payload except SSH_Socket.InsufficientReadException as ex: if ex.args[0] is None: header.write(self.read(self.unread_len)) e = header.write_flush().strip() else: e = ex.args[0].encode('utf-8') return -1, e def send_packet(self) -> Tuple[int, Optional[str]]: payload = self.write_flush() padding = -(len(payload) + 5) % 8 if padding < 4: padding += 8 plen = len(payload) + padding + 1 pad_bytes = b'\x00' * padding data = struct.pack('>Ib', plen, padding) + payload + pad_bytes return self.send(data) def is_connected(self) -> bool: """Returns true if this Socket is connected, False otherwise.""" return self.__sock is not None def close(self) -> None: self.__cleanup() self.reset() self.__state = 0 self.__header = [] self.__banner = None def _close_socket(self, s: Optional[socket.socket]) -> None: # pylint: disable=no-self-use try: if s is not None: s.shutdown(socket.SHUT_RDWR) s.close() # pragma: nocover except Exception: pass def __del__(self) -> None: self.__cleanup() def __cleanup(self) -> None: self._close_socket(self.__sock) for fd in self.__sock_map: self._close_socket(self.__sock_map[fd]) self.__sock = None