223 lines
7.4 KiB
Ruby
223 lines
7.4 KiB
Ruby
##
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# $Id$
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##
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##
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# This file is part of the Metasploit Framework and may be subject to
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# redistribution and commercial restrictions. Please see the Metasploit
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# Framework web site for more information on licensing and terms of use.
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# http://metasploit.com/framework/
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##
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require 'msf/core'
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#
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# NOTE: this encoder currently has only be tested using bit 5 set to on.
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#
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# The decoder has been tested with all possible values, but the decoder stub
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# is was not designed to bypass restrictions other than "bit 5 must be on"..
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#
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class Metasploit3 < Msf::Encoder
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# This encoder has a manual ranking because it should only be used in cases
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# where information has been explicitly supplied, specifically
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# BitNumber and BitValue.
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Rank = ManualRanking
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def initialize
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super(
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'Name' => 'Single Static Bit',
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'Version' => '$Revision$',
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'Description' => 'Static value for specific bit',
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'Author' => 'jduck',
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'Arch' => ARCH_X86,
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'License' => MSF_LICENSE,
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'EncoderType' => Msf::Encoder::Type::SingleStaticBit
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)
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# this shouldn't be present in the decoder stub.
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@key_marker = 0x1010
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end
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#
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# Returns the decoder stub that is adjusted for the size of
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# the buffer being encoded
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#
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def decoder_stub(state)
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bit_num = (datastore['BitNumber'] || 5).to_i
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bit_val = (datastore['BitValue'] || true)
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# variables:
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# bit to ignore (global - harcoded)
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# buf len (can be deduced with a jmp/call/pop) (global - ebx)
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# current source byte ptr (global - esi)
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# current dest byte ptr (global - edi) ?
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# current dest byte (global - ah) ?
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# number of bits accumulated (global - ebp) ?
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# current source byte (outer - al)
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# bit index (for this byte) (inner - cl) ?
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pre_init = ""
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pre_init << "\x31\xed" # xor ebp, ebp - no bits accumulated
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pre_init << "\x83\xe1\x01" # and ecx, $0x1 - init inner loop counter (set to 0/1)
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pre_init << "\x83\xe3\x01" # and ebx, $0x1 - init buffer length
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pre_init << "\x66\xbb" + [@key_marker].pack('v') # - load encrypted buffer length
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pre_init << "\x66\x81\xf3" + [@key_marker].pack('v') # - xor decrypt buffer length
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# we stored an entire byte, move to the next one
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next_byte = ""
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next_byte << "\x83\xef\xff" # sub edi, 0xffffffff - increment dst pointer
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next_byte << "\x31\xed" # xor ebp, ebp - no bits accumulated
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# inside the loop, we need to extract a bit, as
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# specified by:
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#
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# ecx-1 - bit number to extract
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# al - byte to extract it from
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get_a_bit = ""
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get_a_bit << "\x60" # pusha - save all registers
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get_a_bit << "\x83\xe9\x01" # sub ecx, 1 - account for 1-based counting
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get_a_bit << "\x74\x06" # jz +6 - skip dividing if bit zero
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get_a_bit << "\xb3\x02" # mov bl, 2 - set divisor to 2
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# divide_it:
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get_a_bit << "\xf6\xf3" # div bl - do the division
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get_a_bit << "\xe2" + [-1 * (2+2)].pack('C') # - divide again..
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# store_bit:
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get_a_bit << "\x83\xe0\x01" # and eax, 0x01 - we only want the lowest bit
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get_a_bit << "\x6b\x2f\x02" # imul ebp, 2, [edi] - load [edi], shifted left by 1, to ebp
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get_a_bit << "\x09\xe8" # or ebp, eax - set bit 0
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get_a_bit << "\xaa" # stosb al, [edi] - store byte back
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get_a_bit << "\x61" # popa - restore previous ebx/eax
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get_a_bit << "\x83\xed\xff" # sub ebp, 0xffffffff - increment bits stored
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inner_init = ""
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inner_init << "\xb1\x08" # mov cl, $0x8 - init loop counter
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inner_loop = ""
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# process_bits:
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inner_loop << "\x80\xf9" # cmp cl, <ignore_bit + 1> - is this the one to ignore?
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inner_loop << [(bit_num+1)].pack('C')
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len = get_a_bit.length + 3 + 2 + next_byte.length
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inner_loop << "\x74" + [len].pack('C') # - je next_bit
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inner_loop << get_a_bit
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inner_loop << "\x83\xfd\x08" # cmp ebp, $0x8 - got 8 bits now?
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inner_loop << "\x75" + [next_byte.length].pack('C') # - jne to next_bit
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# next_dst_byte:
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inner_loop << next_byte
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# next_bit:
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# I really wish this silly padding wasn't necessary, however removing the bad characters in the
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# jump/call displacements has proven difficult otherwise.
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inner_loop << "\x90" * 0x1a # nops - for padding (so relative jumps don't have badchars)
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len = -1 * (inner_loop.length+2)
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inner_loop << "\xe2" + [len].pack('C') # - loop process_bits
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# prefixed by: # jmp data_beg_call
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outer_init = ""
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# get_data_beg:
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outer_init << "\x5e" # pop esi - ptr to beginning of data
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outer_init << pre_init
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outer_init << "\x89\xf7" # mov edi, esi - decode in place, init dst ptr
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outer_loop = ""
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#outer_loop << "\x90" * (0xd+6)
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outer_loop << "\x83\xe0\x7f" # and eax, 0x7f - we only want the low byte
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outer_loop << "\xac" # lods al, [esi] - load src byte
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outer_loop << inner_init << inner_loop
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outer_loop << "\x83\xeb\x01" # sub ebx, 1 - 1 byte down!
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outer_loop << "\x74\x07" # jz +(2+5) - jump to data!
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len = -1 * (outer_loop.length+2)
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# next_byte:
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outer_loop << "\xeb" + [len].pack('C') # - jmp process_byte
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# data_beg_call:
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decoder = outer_init + outer_loop
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jmp = "\xeb" + [decoder.length].pack('C')
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call = "\xe8" + [-1 * (decoder.length+5)].pack('V')
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decoder = jmp + decoder + call
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# encoded sled
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state.context = ''
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return decoder
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end
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def encode_block(state, block)
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bit_num = (datastore['BitNumber'] || 5).to_i
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bit_num = (7-bit_num)
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bit_val = (datastore['BitValue'] || true)
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encoded = ''
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new_byte = 0
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nbits = 0
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block.unpack('C*').each do |ch|
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7.step(0,-1) do |x|
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# is this the special bit?
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if (nbits == bit_num)
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new_byte <<= 1 if nbits > 0
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new_byte |= 1 if bit_val
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nbits += 1
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# do we have a full byte?
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if nbits == 8
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encoded << new_byte.chr
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new_byte = 0
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nbits = 0
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end
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end
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# we have space, add it in
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new_byte <<= 1 if nbits > 0
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new_byte += 1 if (((ch >> x) & 1) > 0)
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nbits += 1
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# do we have a full byte?
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if nbits == 8
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encoded << new_byte.chr
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new_byte = 0
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nbits = 0
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end
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end
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end
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# if we have bits left, pad out to a whole byte
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if nbits > 0
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while nbits < 8
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new_byte <<= 1
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new_byte |= 1 if (nbits == bit_num) and bit_val
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nbits += 1
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end
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encoded << new_byte.chr
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end
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return encoded
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end
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#
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# Appends the encoded context portion.
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#
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def encode_end(state)
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state.encoded += state.context
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xor_key = 0
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xor_key_str = ''
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enc_len_str = ''
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loop do
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xor_key = rand(0x10000)
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xor_key_str = [xor_key].pack('v')
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enc_len_str = [state.encoded.length ^ xor_key].pack('v')
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next if has_badchars?(xor_key_str, state.badchars)
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next if has_badchars?(enc_len_str, state.badchars)
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break
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end
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marker_str = [@key_marker].pack('v')
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state.encoded.sub!(marker_str, enc_len_str)
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state.encoded.sub!(marker_str, xor_key_str)
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end
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end
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