# # Copyright (c) 2006-2011 Hal Brodigan (postmodern.mod3 at gmail.com) # # This file is part of Ronin Support. # # Ronin Support is free software: you can redistribute it and/or modify # it under the terms of the GNU Lesser General Public License as published # by the Free Software Foundation, either version 3 of the License, or # (at your option) any later version. # # Ronin Support is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public License # along with Ronin Support. If not, see . # require 'ronin/formatting/extensions/binary/integer' require 'ronin/formatting/extensions/text' require 'base64' require 'enumerator' begin require 'zlib' rescue Gem::LoadError => e raise(e) rescue ::LoadError end class String # # Packs an Integer from a String, which was originally packed for # a specific architecture and address-length. # # @param [Ronin::Arch, #endian, #address_length, String] arch # The architecture that the Integer was originally packed with. # # @param [Integer] address_length # The number of bytes to depack. # # @return [Integer] # The depacked Integer. # # @raise [ArgumentError] # The given `arch` does not respond to the `endian` or # `address_length` methods. # # @example using archs other than `Ronin::Arch`. # arch = OpenStruct.new(:endian => :little, :address_length => 4) # # "A\0\0\0".depack(arch) # # => 65 # # @example using a `Ronin::Arch` arch. # "A\0\0\0".depack(Arch.i386) # # => 65 # # @example specifying a custom address-length. # "A\0".depack(Arch.ppc,2) # # => 65 # # @example using a `String#unpack` template String as the arch. # "A\0\0\0".depack('L') # # => 65 # # @see http://ruby-doc.org/core/classes/String.html#M000760 # # @api public # def depack(arch,address_length=nil) if arch.kind_of?(String) return self.unpack(arch) end unless arch.respond_to?(:address_length) raise(ArgumentError,"first argument to Ineger#pack must respond to address_length") end unless arch.respond_to?(:endian) raise(ArgumentError,"first argument to Ineger#pack must respond to endian") end endian = arch.endian.to_sym address_length ||= arch.address_length integer = 0x0 byte_index = 0 case endian when :little mask = lambda { |b| b << (byte_index * 8) } when :big mask = lambda { |b| b << ((address_length - byte_index - 1) * 8) } else raise(ArgumentError,"invalid endian #{arch.endian.inspect}") end each_byte do |b| break if byte_index >= address_length integer |= mask.call(b) byte_index += 1 end return integer end # # Hex-escapes characters in the String. # # @return [String] # The hex escaped version of the String. # # @example # "hello".hex_escape # # => "\\x68\\x65\\x6c\\x6c\\x6f" # # @see String#format_bytes # # @api public # def hex_escape(options={}) format_bytes(options) { |b| b.hex_escape } end # # Unescapes the hex-escaped String. # # @return [String] # The unescaped version of the hex escaped String. # # @example # "\\x68\\x65\\x6c\\x6c\\x6f".hex_unescape # # => "hello" # # @api public # def hex_unescape buffer = '' hex_index = 0 hex_length = length while (hex_index < hex_length) hex_substring = self[hex_index..-1] if hex_substring =~ /^\\[0-7]{3}/ buffer << hex_substring[0..3].to_i(8) hex_index += 3 elsif hex_substring =~ /^\\x[0-9a-fA-F]{1,2}/ hex_substring[2..-1].scan(/^[0-9a-fA-F]{1,2}/) do |hex_byte| buffer << hex_byte.to_i(16) hex_index += (2 + hex_byte.length) end elsif hex_substring =~ /^\\./ escaped_char = hex_substring[1..1] buffer << case escaped_char when '0' "\0" when 'a' "\a" when 'b' "\b" when 't' "\t" when 'n' "\n" when 'v' "\v" when 'f' "\f" when 'r' "\r" else escaped_char end hex_index += 2 else buffer << hex_substring[0] hex_index += 1 end end return buffer end # # XOR encodes the String. # # @param [Enumerable, Integer] key # The byte to XOR against each byte in the String. # # @return [String] # The XOR encoded String. # # @example # "hello".xor(0x41) # # => ")$--." # # @example # "hello again".xor([0x55, 0x41, 0xe1]) # # => "=$\x8d9.\xc14&\x80 "aGVsbG8=\n" # # @api public # def base64_encode Base64.encode64(self) end # # Base64 decodes a string. # # @return [String] # The base64 decoded form of the string. # # @example # "aGVsbG8=\n" # # => "hello" # # @api public # def base64_decode Base64.decode64(self) end # # Zlib inflate a string. # # @return [String] # The Zlib inflated form of the string. # # @example # "x\x9C\xCBH\xCD\xC9\xC9\a\x00\x06,\x02\x15".zlib_inflate # # => "hello" # # @api public # def zlib_inflate Zlib::Inflate.inflate(self) end # # Zlib deflate a string. # # @return [String] # The Zlib deflated form of the string. # # @example # "hello".zlib_deflate # # => "x\x9C\xCBH\xCD\xC9\xC9\a\x00\x06,\x02\x15" # # @api public # def zlib_deflate Zlib::Deflate.deflate(self) end # # Converts a multitude of hexdump formats back into raw-data. # # @param [Hash] options # Additional options. # # @option options [Symbol] :format # The expected format of the hexdump. Must be either `:od` or # `:hexdump`. # # @option options [Symbol] :encoding # Denotes the encoding used for the bytes within the hexdump. # Must be one of the following: # # * `:binary` # * `:octal` # * `:octal_bytes` # * `:octal_shorts` # * `:octal_ints` # * `:octal_quads` # * `:decimal` # * `:decimal_bytes` # * `:decimal_shorts` # * `:decimal_ints` # * `:decimal_quads` # * `:hex` # * `:hex_bytes` # * `:hex_shorts` # * `:hex_ints` # * `:hex_quads` # # @option options [Integer] :segment (16) # The length in bytes of each segment in the hexdump. # # @return [String] The raw-data from the hexdump. # # @api public # def unhexdump(options={}) case (format = options[:format]) when :od address_base = 8 base = 8 word_size = 2 when :hexdump address_base = 16 base = 16 word_size = 2 else address_base = 16 base = 16 word_size = 1 end case options[:encoding] when :binary base = 2 when :octal, :octal_bytes, :octal_shorts, :octal_ints, :octal_quads base = 8 when :decimal, :decimal_bytes, :decimal_shorts, :decimal_ints, :decimal_quads base = 10 when :hex, :hex_bytes, :hex_shorts, :hex_ints, :hex_quads base = 16 end case options[:encoding] when :binary, :octal_bytes, :decimal_bytes, :hex_bytes word_size = 1 when :octal_shorts, :decimal_shorts, :hex_shorts word_size = 2 when :octal_ints, :decimal_ints, :hex_ints word_size = 4 when :octal_quads, :decimal_quads, :hex_quads word_size = 8 end current_addr = last_addr = first_addr = nil repeated = false segment_length = (options[:segment] || 16) segment = [] buffer = [] each_line do |line| if format == :hexdump line = line.gsub(/\s+\|.+\|\s*$/,'') end words = line.split if words.first == '*' repeated = true elsif words.length > 0 current_addr = words.shift.to_i(address_base) first_addr ||= current_addr if repeated (((current_addr - last_addr) / segment.length) - 1).times do buffer += segment end repeated = false end segment.clear words.each do |word| if (base != 10 && word =~ /^(\\[0abtnvfr\\]|.)$/) word.hex_unescape.each_byte { |b| segment << b } else segment += word.to_i(base).bytes(word_size) end end segment = segment[0,segment_length] buffer += segment last_addr = current_addr end end return buffer[0,(last_addr - first_addr)] end end