require 'socket' require 'thread' require 'resolv' require 'rex/exceptions' module Rex ### # # Base class for all sockets. # ### module Socket module Comm end require 'rex/socket/parameters' require 'rex/socket/tcp' require 'rex/socket/tcp_server' require 'rex/socket/comm' require 'rex/socket/comm/local' require 'rex/socket/switch_board' require 'rex/socket/subnet_walker' require 'rex/socket/range_walker' ## # # Factory methods # ## # # Create a socket instance using the supplied parameter hash. # def self.create(opts = {}) return create_param(Rex::Socket::Parameters.from_hash(opts)) end # # Create a socket using the supplied Rex::Socket::Parameter instance. # def self.create_param(param) return param.comm.create(param) end # # Create a TCP socket using the supplied parameter hash. # def self.create_tcp(opts = {}) return create_param(Rex::Socket::Parameters.from_hash(opts.merge('Proto' => 'tcp'))) end # # Create a TCP server socket using the supplied parameter hash. # def self.create_tcp_server(opts = {}) return create_tcp(opts.merge('Server' => true)) end # # Create a UDP socket using the supplied parameter hash. # def self.create_udp(opts = {}) return create_param(Rex::Socket::Parameters.from_hash(opts.merge('Proto' => 'udp'))) end # # Create a IP socket using the supplied parameter hash. # def self.create_ip(opts = {}) return create_param(Rex::Socket::Parameters.from_hash(opts.merge('Proto' => 'ip'))) end # # Common Regular Expressions # MATCH_IPV6 = /^\s*((([0-9A-Fa-f]{1,4}:){7}([0-9A-Fa-f]{1,4}|:))|(([0-9A-Fa-f]{1,4}:){6}(:[0-9A-Fa-f]{1,4}|((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3})|:))|(([0-9A-Fa-f]{1,4}:){5}(((:[0-9A-Fa-f]{1,4}){1,2})|:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3})|:))|(([0-9A-Fa-f]{1,4}:){4}(((:[0-9A-Fa-f]{1,4}){1,3})|((:[0-9A-Fa-f]{1,4})?:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:))|(([0-9A-Fa-f]{1,4}:){3}(((:[0-9A-Fa-f]{1,4}){1,4})|((:[0-9A-Fa-f]{1,4}){0,2}:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:))|(([0-9A-Fa-f]{1,4}:){2}(((:[0-9A-Fa-f]{1,4}){1,5})|((:[0-9A-Fa-f]{1,4}){0,3}:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:))|(([0-9A-Fa-f]{1,4}:){1}(((:[0-9A-Fa-f]{1,4}){1,6})|((:[0-9A-Fa-f]{1,4}){0,4}:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:))|(:(((:[0-9A-Fa-f]{1,4}){1,7})|((:[0-9A-Fa-f]{1,4}){0,5}:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:)))(%.+)?\s*$/ MATCH_IPV4 = /^\s*(?:(?:25[0-5]|2[0-4][0-9]|[0-1]?[0-9]{1,2})[.](?:25[0-5]|2[0-4][0-9]|[0-1]?[0-9]{1,2})[.](?:25[0-5]|2[0-4][0-9]|[0-1]?[0-9]{1,2})[.](?:25[0-5]|2[0-4][0-9]|[0-1]?[0-9]{1,2}))\s*$/ MATCH_IPV4_PRIVATE = /^\s*(?:10\.|192\.168|172.(?:1[6-9]|2[0-9]|3[01])\.|169\.254)/ ## # # Serialization # ## # Cache our IPv6 support flag @@support_ipv6 = nil # # Determine whether we support IPv6 # def self.support_ipv6? return @@support_ipv6 if not @@support_ipv6.nil? @@support_ipv6 = false if (::Socket.const_defined?('AF_INET6')) begin s = ::Socket.new(::Socket::AF_INET6, ::Socket::SOCK_DGRAM, ::Socket::IPPROTO_UDP) s.close @@support_ipv6 = true rescue end end return @@support_ipv6 end # # Determine whether this is an IPv4 address # def self.is_ipv4?(addr) return false if addr =~ MATCH_IPV6 return true if addr =~ MATCH_IPV4 res = Rex::Socket.getaddress(addr) res.match(/:/) ? false : true end # # Determine whether this is an IPv6 address # def self.is_ipv6?(addr) return true if addr =~ MATCH_IPV6 return false if addr =~ MATCH_IPV4 res = Rex::Socket.getaddress(addr) res.match(/:/) ? true : false end # # Checks to see if the supplied address is in "dotted" form # def self.dotted_ip?(addr) # Match IPv6 return true if (support_ipv6? and addr =~ MATCH_IPV6) # Match IPv4 return true if (addr =~ MATCH_IPV4) false end # # Return true if +addr+ is within the ranges specified in RFC1918, or # RFC5735/RFC3927 # def self.is_internal?(addr) if self.dotted_ip?(addr) addr =~ MATCH_IPV4_PRIVATE else false end end # # Wrapper for Resolv.getaddress that takes special care to see if the # supplied address is already a dotted quad, for instance. This is # necessary to prevent calls to gethostbyaddr (which occurs on windows). # These calls can be quite slow. This also fixes an issue with the # Resolv.getaddress() call being non-functional on Ruby 1.9.1 (Win32). # def self.getaddress(addr, accept_ipv6 = true) begin if addr =~ MATCH_IPV4 or (accept_ipv6 and addr =~ MATCH_IPV6) return addr end res = ::Socket.gethostbyname(addr) return nil if not res # Shift the first three elements out rname = res.shift ralias = res.shift rtype = res.shift # Reject IPv6 addresses if we don't accept them if not accept_ipv6 res.reject!{|nbo| nbo.length != 4} end # Make sure we have at least one name return nil if res.length == 0 # Return the first address of the result self.addr_ntoa( res[0] ) rescue ::ArgumentError # Win32 bug nil end end # # Wrapper for Resolv.getaddress that takes special care to see if the # supplied address is already a dotted quad, for instance. This is # necessary to prevent calls to gethostbyaddr (which occurs on windows). # These calls can be quite slow. This also fixes an issue with the # Resolv.getaddress() call being non-functional on Ruby 1.9.1 (Win32). # def self.getaddresses(addr, accept_ipv6 = true) begin if addr =~ MATCH_IPV4 or (accept_ipv6 and addr =~ MATCH_IPV6) return [addr] end res = ::Socket.gethostbyname(addr) return [] if not res # Shift the first three elements out rname = res.shift ralias = res.shift rtype = res.shift # Reject IPv6 addresses if we don't accept them if not accept_ipv6 res.reject!{|nbo| nbo.length != 4} end # Make sure we have at least one name return [] if res.length == 0 # Return an array of all addresses res.map{ |addr| self.addr_ntoa(addr) } rescue ::ArgumentError # Win32 bug [] end end # # Wrapper for Socket.gethostbyname which takes into account whether or not # an IP address is supplied. If it is, then reverse DNS resolution does # not occur. This is done in order to prevent delays, such as would occur # on Windows. # def self.gethostbyname(host) if (dotted_ip?(host)) if (is_ipv4?(host)) return [ host, host, 2, host.split('.').map{ |c| c.to_i }.pack("C4") ] end end ::Socket.gethostbyname(host) end # # Create a sockaddr structure using the supplied IP address, port, and # address family # def self.to_sockaddr(ip, port) if (ip == '::ffff:0.0.0.0') ip = support_ipv6?() ? '::' : '0.0.0.0' end return ::Socket.pack_sockaddr_in(port, ip) end # # Returns the address family, host, and port of the supplied sockaddr as # [ af, host, port ] # def self.from_sockaddr(saddr) port, host = ::Socket::unpack_sockaddr_in(saddr) af = ::Socket::AF_INET if (support_ipv6?() and is_ipv6?(host)) af = ::Socket::AF_INET6 end return [ af, host, port ] end # # Resolves a host to raw network-byte order. # def self.resolv_nbo(host) self.gethostbyname(Rex::Socket.getaddress(host))[3] end # # Resolves a host to raw network-byte order. # def self.resolv_nbo_list(host) Rex::Socket.getaddresses(host).map{|addr| self.gethostbyname(addr)[3] } end # # Resolves a host to a network-byte order ruby integer. # def self.resolv_nbo_i(host) addr_ntoi(resolv_nbo(host)) end # # Resolves a host to a list of network-byte order ruby integers. # def self.resolv_nbo_i_list(host) resolv_nbo_list(host).map{|addr| addr_ntoi(addr) } end # # Converts an ASCII IP address to a CIDR mask. Returns # nil if it's not convertable. # def self.addr_atoc(mask) mask_i = resolv_nbo_i(mask) cidr = nil 0.upto(32) do |i| if ((1 << i)-1) << (32-i) == mask_i cidr = i break end end return cidr end # # Resolves a CIDR bitmask into a dotted-quad. Returns # nil if it's not convertable. # def self.addr_ctoa(cidr) return nil unless (0..32) === cidr.to_i addr_itoa(((1 << cidr)-1) << 32-cidr) end # # Resolves a host to a dotted address. # def self.resolv_to_dotted(host) addr_ntoa(addr_aton(host)) end # # Converts a ascii address into an integer # def self.addr_atoi(addr) resolv_nbo_i(addr) end # # Converts a ascii address into a list of addresses # def self.addr_atoi_list(addr) resolv_nbo_i_list(addr) end # # Converts an integer address into ascii # def self.addr_itoa(addr, v6=false) nboa = addr_iton(addr, v6) # IPv4 if (addr < 0x100000000 and not v6) addr_ntoa(nboa) # IPv6 else addr_ntoa(nboa) end end # # Converts a ascii address to network byte order # def self.addr_aton(addr) resolv_nbo(addr) end # # Converts a network byte order address to ascii # def self.addr_ntoa(addr) # IPv4 if (addr.length == 4) return addr.unpack('C4').join('.') end # IPv6 if (addr.length == 16) return compress_address(addr.unpack('n8').map{ |c| "%x" % c }.join(":")) end raise RuntimeError, "Invalid address format" end # # Implement zero compression for IPv6 addresses. # Uses the compression method from Marco Ceresa's IPAddress GEM # https://github.com/bluemonk/ipaddress/blob/master/lib/ipaddress/ipv6.rb # def self.compress_address(addr) return addr unless is_ipv6?(addr) addr = addr.dup while true break if addr.sub!(/\A0:0:0:0:0:0:0:0\Z/, '::') break if addr.sub!(/\b0:0:0:0:0:0:0\b/, ':') break if addr.sub!(/\b0:0:0:0:0:0\b/, ':') break if addr.sub!(/\b0:0:0:0:0\b/, ':') break if addr.sub!(/\b0:0:0:0\b/, ':') break if addr.sub!(/\b0:0:0\b/, ':') break if addr.sub!(/\b0:0\b/, ':') break end addr.sub(/:{3,}/, '::') end # # Converts a network byte order address to an integer # def self.addr_ntoi(addr) bits = addr.unpack("N*") if (bits.length == 1) return bits[0] end if (bits.length == 4) val = 0 bits.each_index { |i| val += ( bits[i] << (96 - (i * 32)) ) } return val end raise RuntimeError, "Invalid address format" end # # Converts an integer into a network byte order address # def self.addr_iton(addr, v6=false) if(addr < 0x100000000 and not v6) return [addr].pack('N') else w = [] w[0] = (addr >> 96) & 0xffffffff w[1] = (addr >> 64) & 0xffffffff w[2] = (addr >> 32) & 0xffffffff w[3] = addr & 0xffffffff return w.pack('N4') end end # # Converts a CIDR subnet into an array (base, bcast) # def self.cidr_crack(cidr, v6=false) tmp = cidr.split('/') tst,scope = tmp[0].split("%",2) scope = "%" + scope if scope scope ||= "" addr = addr_atoi(tst) bits = 32 mask = 0 use6 = false if (addr > 0xffffffff or v6 or cidr =~ /:/) use6 = true bits = 128 end mask = (2 ** bits) - (2 ** (bits - tmp[1].to_i)) base = addr & mask stop = base + (2 ** (bits - tmp[1].to_i)) - 1 return [self.addr_itoa(base, use6) + scope, self.addr_itoa(stop, use6) + scope] end # # Converts a netmask (255.255.255.240) into a bitmask (28). This is the # lame kid way of doing it. # def self.net2bitmask(netmask) nmask = resolv_nbo(netmask) imask = addr_ntoi(nmask) bits = 32 if (imask > 0xffffffff) bits = 128 end 0.upto(bits-1) do |bit| p = 2 ** bit return (bits - bit) if ((imask & p) == p) end 0 end # # Converts a bitmask (28) into a netmask (255.255.255.240) # TODO: IPv6 (use is ambiguous right now) # def self.bit2netmask(bitmask) [ (~((2 ** (32 - bitmask)) - 1)) & 0xffffffff ].pack('N').unpack('CCCC').join('.') end def self.portspec_crack(pspec) portspec_to_portlist(pspec) end # # Converts a port specification like "80,21-23,443" into a sorted, # unique array of valid port numbers like [21,22,23,80,443] # def self.portspec_to_portlist(pspec) ports = [] # Build ports array from port specification pspec.split(/,/).each do |item| start, stop = item.split(/-/).map { |p| p.to_i } start ||= 0 stop ||= item.match(/-/) ? 65535 : start start, stop = stop, start if stop < start start.upto(stop) { |p| ports << p } end # Sort, and remove dups and invalid ports ports.sort.uniq.delete_if { |p| p < 1 or p > 65535 } end # # Converts a port list like [1,2,3,4,5,100] into a # range specification like "1-5,100" # def self.portlist_to_portspec(parr) ranges = [] range = [] lastp = nil parr.uniq.sort{|a,b| a<=>b}.map{|a| a.to_i}.each do |n| next if (n < 1 or n > 65535) if not lastp range = [n] lastp = n next end if lastp == n - 1 range << n else ranges << range range = [n] end lastp = n end ranges << range ranges.delete(nil) ranges.uniq.map{|x| x.length == 1 ? "#{x[0]}" : "#{x[0]}-#{x[-1]}"}.join(",") end ## # # Utility class methods # ## # # This method does NOT send any traffic to the destination, instead, it uses a # "bound" UDP socket to determine what source address we would use to # communicate with the specified destination. The destination defaults to # Google's DNS server to make the standard behavior determine which IP # we would use to communicate with the internet. # def self.source_address(dest='8.8.8.8', comm = ::Rex::Socket::Comm::Local) begin s = self.create_udp( 'PeerHost' => dest, 'PeerPort' => 31337, 'Comm' => comm ) r = s.getsockname[1] s.close # Trim off the trailing interface ID for link-local IPv6 return r.split('%').first rescue ::Exception return '127.0.0.1' end end # # Identifies the link-local address of a given interface (if IPv6 is enabled) # def self.ipv6_link_address(intf) r = source_address("FF02::1%#{intf}") return if not (r and r =~ /^fe80/i) r end # # Identifies the mac address of a given interface (if IPv6 is enabled) # def self.ipv6_mac(intf) r = ipv6_link_address(intf) return if not r raw = addr_aton(r)[-8, 8] (raw[0,3] + raw[5,3]).unpack("C*").map{|c| "%.2x" % c}.join(":") end # # Create a TCP socket pair. # # sf: This create a socket pair using native ruby sockets and will work # on Windows where ::Socket.pair is not implemented. # Note: OpenSSL requires native ruby sockets for its io. # # Note: Even though sub-threads are smashing the parent threads local, there # is no concurrent use of the same locals and this is safe. def self.tcp_socket_pair lsock = nil rsock = nil laddr = '127.0.0.1' lport = 0 threads = [] mutex = ::Mutex.new threads << Rex::ThreadFactory.spawn('TcpSocketPair', false) { server = nil mutex.synchronize { threads << Rex::ThreadFactory.spawn('TcpSocketPairClient', false) { mutex.synchronize { rsock = ::TCPSocket.new( laddr, lport ) } } server = ::TCPServer.new(laddr, 0) if (server.getsockname =~ /127\.0\.0\.1:/) # JRuby ridiculousness caddr, lport = server.getsockname.split(":") caddr = caddr[1,caddr.length] lport = lport.to_i else # Sane implementations where Socket#getsockname returns a # sockaddr lport, caddr = ::Socket.unpack_sockaddr_in( server.getsockname ) end } lsock, saddr = server.accept server.close } threads.each { |t| t.join } return [lsock, rsock] end # # Create a UDP socket pair using native ruby UDP sockets. # def self.udp_socket_pair laddr = '127.0.0.1' lsock = ::UDPSocket.new lsock.bind( laddr, 0 ) rsock = ::UDPSocket.new rsock.bind( laddr, 0 ) rsock.connect( *lsock.addr.values_at(3,1) ) lsock.connect( *rsock.addr.values_at(3,1) ) return [lsock, rsock] end ## # # Class initialization # ## # # Initialize general socket parameters. # def initsock(params = nil) if (params) self.peerhost = params.peerhost self.peerport = params.peerport self.localhost = params.localhost self.localport = params.localport self.context = params.context || {} self.ipv = params.v6 ? 6 : 4 end end # # By default, all sockets are themselves selectable file descriptors. # def fd self end # # Returns local connection information. # def getsockname Socket.from_sockaddr(super) end # # Wrapper around getsockname # def getlocalname getsockname end # # Return peer connection information. # def getpeername return Socket.from_sockaddr(super) end # # Returns a string that indicates the type of the socket, such as 'tcp'. # def type? raise NotImplementedError, "Socket type is not supported." end # # The peer host of the connected socket. # attr_reader :peerhost # # The peer port of the connected socket. # attr_reader :peerport # # The local host of the connected socket. # attr_reader :localhost # # The local port of the connected socket. # attr_reader :localport # # The IP version of the socket # attr_reader :ipv # # Contextual information that describes the source and other # instance-specific attributes. This comes from the param.context # attribute. # attr_reader :context protected attr_writer :peerhost, :peerport, :localhost, :localport # :nodoc: attr_writer :context # :nodoc: attr_writer :ipv # :nodoc: end end # # Globalized socket constants # SHUT_RDWR = ::Socket::SHUT_RDWR SHUT_RD = ::Socket::SHUT_RD SHUT_WR = ::Socket::SHUT_WR