# -*- coding: binary -*- require 'msf/core' module Msf ### # # This class wrappers an encoded payload buffer and the means used to create # one. # ### class EncodedPayload include Framework::Offspring # # This method creates an encoded payload instance and returns it to the # caller. # def self.create(pinst, reqs = {}) # Create the encoded payload instance p = EncodedPayload.new(pinst.framework, pinst, reqs) p.generate(reqs['Raw']) return p end # # Creates an instance of an EncodedPayload. # def initialize(framework, pinst, reqs) self.framework = framework self.pinst = pinst self.reqs = reqs end # # This method generates the full encoded payload and returns the encoded # payload buffer. # # @return [String] The encoded payload. def generate(raw = nil) self.raw = raw self.encoded = nil self.nop_sled_size = 0 self.nop_sled = nil self.encoder = nil self.nop = nil self.iterations = reqs['Iterations'].to_i self.iterations = 1 if self.iterations < 1 # Increase thread priority as necessary. This is done # to ensure that the encoding and sled generation get # enough time slices from the ruby thread scheduler. priority = Thread.current.priority if (priority == 0) Thread.current.priority = 1 end begin # First, validate pinst.validate() # Generate the raw version of the payload first generate_raw() if self.raw.nil? # Encode the payload encode() # Build the NOP sled generate_sled() # Finally, set the complete payload definition self.encoded = (self.nop_sled || '') + self.encoded ensure # Restore the thread priority Thread.current.priority = priority end # Return the complete payload return encoded end # # Generates the raw payload from the payload instance. This populates the # {#raw} attribute. # # @return [String] The raw, unencoded payload. def generate_raw self.raw = (reqs['Prepend'] || '') + pinst.generate + (reqs['Append'] || '') # If an encapsulation routine was supplied, then we should call it so # that we can get the real raw payload. if reqs['EncapsulationRoutine'] self.raw = reqs['EncapsulationRoutine'].call(reqs, raw) end end # # Scans for a compatible encoder using ranked precedence and populates the # encoded attribute. # def encode # If the exploit has bad characters, we need to run the list of encoders # in ranked precedence and try to encode without them. if reqs['BadChars'] or reqs['Encoder'] or reqs['ForceEncode'] encoders = pinst.compatible_encoders # Fix encoding issue if reqs['Encoder'] reqs['Encoder'] = reqs['Encoder'].encode(framework.encoders.keys[0].encoding) end # If the caller had a preferred encoder, use this encoder only if ((reqs['Encoder']) and (preferred = framework.encoders[reqs['Encoder']])) encoders = [ [reqs['Encoder'], preferred] ] elsif (reqs['Encoder']) wlog("#{pinst.refname}: Failed to find preferred encoder #{reqs['Encoder']}") raise NoEncodersSucceededError, "Failed to find preferred encoder #{reqs['Encoder']}" end encoders.each { |encname, encmod| self.encoder = encmod.new self.encoded = nil # If the encoding is requested by an exploit check compatibility # options first of all. For the 'generic/none' encoder compatibility # options don't apply. if (reqs['Exploit'] && !reqs['Exploit'].compatible?(self.encoder) && encname !~ /generic\/none/) wlog("#{pinst.refname}: Encoder #{encoder.refname} doesn't match the exploit Compat options", 'core', LEV_1) next end # If there is an encoder type restriction, check to see if this # encoder matches with what we're searching for. if ((reqs['EncoderType']) and (self.encoder.encoder_type.split(/\s+/).include?(reqs['EncoderType']) == false)) wlog("#{pinst.refname}: Encoder #{encoder.refname} is not a compatible encoder type: #{reqs['EncoderType']} != #{self.encoder.encoder_type}", 'core', LEV_1) next end # If the exploit did not explicitly request a kind of encoder and # the current encoder has a manual ranking, then it should not be # considered as a valid encoder. A manual ranking tells the # framework that an encoder must be explicitly defined as the # encoder of choice for an exploit. if ((reqs['EncoderType'].nil?) and (reqs['Encoder'].nil?) and (self.encoder.rank == ManualRanking)) wlog("#{pinst.refname}: Encoder #{encoder.refname} is manual ranked and was not defined as a preferred encoder.", 'core', LEV_1) next end # If the caller explictly requires register preservation, make sure # that the module in question can handle it. This is mostly used by # the stage encoder path. if (reqs['ForceSaveRegisters'] and reqs['EncoderOptions'] and (reqs['EncoderOptions']['SaveRegisters'].to_s.length > 0) and (! self.encoder.preserves_registers?)) wlog("#{pinst.refname}: Encoder #{encoder.refname} does not preserve registers and the caller needs #{reqs['EncoderOptions']['SaveRegisters']} preserved.", 'core', LEV_1) next end # Import the datastore from payload (and likely exploit by proxy) self.encoder.share_datastore(pinst.datastore) # If we have any encoder options, import them into the datastore # of the encoder. if (reqs['EncoderOptions']) self.encoder.datastore.import_options_from_hash(reqs['EncoderOptions']) end # Validate the encoder to make sure it's properly initialized. begin self.encoder.validate rescue ::Exception wlog("#{pinst.refname}: Failed to validate encoder #{encoder.refname}: #{$!}", 'core', LEV_1) next end eout = self.raw.dup next_encoder = false # Try encoding with the current encoder # # NOTE: Using more than one iteration may cause successive iterations to switch # to using a different encoder. # 1.upto(self.iterations) do |iter| err_start = "#{pinst.refname}: iteration #{iter}" begin eout = self.encoder.encode(eout, reqs['BadChars'], nil, pinst.platform) rescue EncodingError wlog("#{err_start}: Encoder #{encoder.refname} failed: #{$!}", 'core', LEV_1) dlog("#{err_start}: Call stack\n#{$@.join("\n")}", 'core', LEV_3) next_encoder = true break rescue ::Exception elog("#{err_start}: Broken encoder #{encoder.refname}: #{$!}", 'core', LEV_0) dlog("#{err_start}: Call stack\n#{$@.join("\n")}", 'core', LEV_1) next_encoder = true break end # Get the minimum number of nops to use min = (reqs['MinNops'] || 0).to_i min = 0 if reqs['DisableNops'] # Check to see if we have enough room for the minimum requirements if ((reqs['Space']) and (reqs['Space'] < eout.length + min)) wlog("#{err_start}: Encoded payload version is too large (#{eout.length} bytes) with encoder #{encoder.refname}", 'core', LEV_1) next_encoder = true break end ilog("#{err_start}: Successfully encoded with encoder #{encoder.refname} (size is #{eout.length})", 'core', LEV_0) end next if next_encoder self.encoded = eout break } # If the encoded payload is nil, raise an exception saying that we # suck at life. if (self.encoded == nil) self.encoder = nil raise NoEncodersSucceededError, "#{pinst.refname}: All encoders failed to encode.", caller end # If there are no bad characters, then the raw is the same as the # encoded else self.encoded = raw end # Prefix the prepend encoder value self.encoded = (reqs['PrependEncoder'] || '') + self.encoded self.encoded << (reqs['AppendEncoder'] || '') end # # Construct a NOP sled if necessary # def generate_sled min = reqs['MinNops'] || 0 space = reqs['Space'] self.nop_sled_size = min # Calculate the number of NOPs to pad out the buffer with based on the # requirements. If there was a space requirement, check to see if # there's any room at all left for a sled. if ((space) and (space > encoded.length)) self.nop_sled_size = reqs['Space'] - self.encoded.length end # If the maximum number of NOPs has been exceeded, wrap it back down. if ((reqs['MaxNops']) and (reqs['MaxNops'] < self.nop_sled_size)) self.nop_sled_size = reqs['MaxNops'] end # Check for the DisableNops setting self.nop_sled_size = 0 if reqs['DisableNops'] # Now construct the actual sled if (self.nop_sled_size > 0) nops = pinst.compatible_nops # If the caller had a preferred nop, try to find it and prefix it if ((reqs['Nop']) and (preferred = framework.nops[reqs['Nop']])) nops.unshift([reqs['Nop'], preferred ]) elsif (reqs['Nop']) wlog("#{pinst.refname}: Failed to find preferred nop #{reqs['Nop']}") end nops.each { |nopname, nopmod| # Create an instance of the nop module self.nop = nopmod.new # Propagate options from the payload and possibly exploit self.nop.share_datastore(pinst.datastore) # The list of save registers save_regs = (reqs['SaveRegisters'] || []) + (pinst.save_registers || []) if (save_regs.empty? == true) save_regs = nil end begin nop.copy_ui(pinst) self.nop_sled = nop.generate_sled(self.nop_sled_size, 'BadChars' => reqs['BadChars'], 'SaveRegisters' => save_regs) rescue dlog("#{pinst.refname}: Nop generator #{nop.refname} failed to generate sled for payload: #{$!}", 'core', LEV_1) self.nop = nil end break } if (self.nop_sled == nil) raise NoNopsSucceededError, "#{pinst.refname}: All NOP generators failed to construct sled for.", caller end else self.nop_sled = '' end return self.nop_sled end # # Convert the payload to an executable appropriate for its arch and # platform. # # +opts+ are passed directly to +Msf::Util::EXE.to_executable+ # # see +Msf::Exploit::EXE+ # def encoded_exe(opts={}) # Ensure arch and platform are in the format that to_executable expects if opts[:arch] and not opts[:arch].kind_of? Array opts[:arch] = [ opts[:arch] ] end if (opts[:platform].kind_of? Msf::Module::PlatformList) opts[:platform] = opts[:platform].platforms end emod = pinst.assoc_exploit if pinst.respond_to? :assoc_exploit if emod if (emod.datastore["EXE::Custom"] and emod.respond_to? :get_custom_exe) return emod.get_custom_exe end # This is a little ghetto, grabbing datastore options from the # associated exploit, but it doesn't really make sense for the # payload to have exe options if the exploit doesn't need an exe. # Msf::Util::EXE chooses reasonable defaults if these aren't given, # so it's not that big of an issue. opts.merge!({ :template_path => emod.datastore['EXE::Path'], :template => emod.datastore['EXE::Template'], :inject => emod.datastore['EXE::Inject'], :fallback => emod.datastore['EXE::FallBack'], :sub_method => emod.datastore['EXE::OldMethod'] }) # Prefer the target's platform/architecture information, but use # the exploit module's if no target specific information exists. opts[:platform] ||= emod.target_platform if emod.respond_to? :target_platform opts[:platform] ||= emod.platform if emod.respond_to? :platform opts[:arch] ||= emod.target_arch if emod.respond_to? :target_arch opts[:arch] ||= emod.arch if emod.respond_to? :arch end # Lastly, try the payload's. This always happens if we don't have an # associated exploit module. opts[:platform] ||= pinst.platform if pinst.respond_to? :platform opts[:arch] ||= pinst.arch if pinst.respond_to? :arch Msf::Util::EXE.to_executable(framework, opts[:arch], opts[:platform], encoded, opts) end # # Generate a jar file containing the encoded payload. # # Uses the payload's +generate_jar+ method if it is implemented (Java # payloads should all have it). Otherwise, converts the payload to an # executable and uses Msf::Util::EXE.to_jar to create a jar file that dumps # the exe out to a random file name in the system's temporary directory and # executes it. # def encoded_jar(opts={}) return pinst.generate_jar(opts) if pinst.respond_to? :generate_jar opts[:spawn] ||= pinst.datastore["Spawn"] Msf::Util::EXE.to_jar(encoded_exe(opts), opts) end # # Similar to +encoded_jar+ but builds a web archive for use in servlet # containers such as Tomcat. # def encoded_war(opts={}) return pinst.generate_war(opts) if pinst.respond_to? :generate_war Msf::Util::EXE.to_jsp_war(encoded_exe(opts), opts) end # # An array containing the architecture(s) that this payload was made to run on # def arch if pinst pinst.arch end end # # The raw version of the payload # attr_reader :raw # # The encoded version of the raw payload plus the NOP sled # if one was generated. # attr_reader :encoded # # The size of the NOP sled # attr_reader :nop_sled_size # # The NOP sled itself # attr_reader :nop_sled # # The encoder that was used # attr_reader :encoder # # The NOP generator that was used # attr_reader :nop # # The number of encoding iterations used # attr_reader :iterations protected attr_writer :raw # :nodoc: attr_writer :encoded # :nodoc: attr_writer :nop_sled_size # :nodoc: attr_writer :nop_sled # :nodoc: attr_writer :payload # :nodoc: attr_writer :encoder # :nodoc: attr_writer :nop # :nodoc: attr_writer :iterations # :nodoc: # # The payload instance used to generate the payload # attr_accessor :pinst # # The requirements used for generation # attr_accessor :reqs end end