mirror of
https://github.com/mgeeky/Penetration-Testing-Tools.git
synced 2024-11-22 10:31:38 +01:00
578 lines
18 KiB
Python
578 lines
18 KiB
Python
#!/usr/bin/python
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#
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# ReEncoder.py - script allowing for recursive encoding detection, decoding and then re-encoding.
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# To be used for instance in fuzzing purposes. Imagine you want to fuzz XML parameters within
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# **PaReq** packet of 3DSecure standard. This packet has been ZLIB compressed, then Base64 encoded,
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# then URLEncoded. In order to modify the inner XML you would need to peel off that encoding layers
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# and then reaplly them in reversed order. This script allows you to do that in an automated manner
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#
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# NOTICE:
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# If the input string's length is divisble by 4, Base64 will be able to decode it - thus, the script
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# would wrongly assume it has been encoded using Base64. The same goes for Hex decoding.
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# In order to tackle this issue, the script builds up a tree of possible encoding schemes and then evaluate
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# that tree by choosing the best fitting encodings path (with most points counted upon resulted text's length,
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# entropy and printable'ity).
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#
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# Requires:
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# - jwt
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# - anytree
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#
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# Mariusz Banach, 2018
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#
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import os
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import re
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import sys
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import jwt
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import zlib
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import math
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import base64
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import urllib
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import string
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import anytree
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import binascii
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from collections import Counter
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# =============================================
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# RE-ENCODER'S IMPLEMENTATION
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#
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class ReEncoder:
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# Switch this to show some verbose informations about decoding process.
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DEBUG = True
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PREFER_AUTO = 0 # Automatically determine final output format
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PREFER_TEXT = 1 # Prefer text/printable final output format
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PREFER_BINARY = 2 # Prefer binary final output format
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class Utils:
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@staticmethod
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def isBinaryData(data):
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nonBinary = 0
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percOfBinaryToAssume = 0.10
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for d in data:
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c = ord(d)
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if c in (10, 13):
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nonBinary += 1
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elif c >= 0x20 and c <= 0x7f:
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nonBinary += 1
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binary = len(data) - nonBinary
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return binary >= int(percOfBinaryToAssume * len(data))
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# ============================================================
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# ENCODERS SECTION
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#
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class Encoder:
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def name(self):
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raise NotImplementedError
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def check(self, data):
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raise NotImplementedError
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def encode(self, data):
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raise NotImplementedError
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def decode(self, data):
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raise NotImplementedError
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class NoneEncoder(Encoder):
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def name(self):
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return 'None'
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def check(self, data):
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if not data:
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return False
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return True
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def encode(self, data):
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return data
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def decode(self, data):
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return data
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class URLEncoder(Encoder):
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def name(self):
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return 'URLEncoder'
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def check(self, data):
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if urllib.quote(urllib.unquote(data)) == data and (urllib.unquote(data) != data):
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return True
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if re.search(r'(?:%[0-9a-f]{2})+', data, re.I):
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return True
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return False
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def encode(self, data):
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return urllib.quote(data)
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def decode(self, data):
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return urllib.unquote(data)
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class HexEncoder(Encoder):
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def name(self):
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return 'HexEncoded'
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def check(self, data):
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m = re.match(r'^[0-9a-f]+$', data, re.I)
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if m:
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return True
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return False
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def encode(self, data):
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return binascii.hexlify(data).strip()
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def decode(self, data):
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return binascii.unhexlify(data).strip()
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class Base64Encoder(Encoder):
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def name(self):
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return 'Base64'
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def check(self, data):
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try:
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if base64.b64encode(base64.b64decode(data)) == data:
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m = re.match('^(?:[A-Za-z0-9+\/]{4})*(?:[A-Za-z0-9+\/]{2}==|[A-Za-z0-9+\/]{3}=|[A-Za-z0-9+\/]{4})$', data, re.I)
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if m:
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return True
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return False
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except:
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pass
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return False
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def encode(self, data):
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return base64.b64encode(data)
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def decode(self, data):
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return base64.b64decode(data)
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class Base64URLSafeEncoder(Encoder):
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def name(self):
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return 'Base64URLSafe'
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def check(self, data):
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try:
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if base64.urlsafe_b64encode(base64.urlsafe_b64decode(data)) == data:
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m = re.match('^(?:[A-Za-z0-9\-_]{4})*(?:[A-Za-z0-9\-_]{2}==|[A-Za-z0-9\-_]{3}=|[A-Za-z0-9\-_]{4})$', data, re.I)
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if m:
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return True
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return False
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except:
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pass
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return False
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def encode(self, data):
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return base64.urlsafe_b64encode(data)
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def decode(self, data):
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return base64.urlsafe_b64decode(data)
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class JWTEncoder(Encoder):
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secret = ''
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def name(self):
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return 'JWT'
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def check(self, data):
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try:
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jwt.decode(data, verify = False)
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return True
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except jwt.exceptions.DecodeError:
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return False
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def encode(self, data):
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return jwt.encode(data, JWTEncoder.secret)
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def decode(self, data):
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return jwt.decode(data, verify = False)
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class ZlibEncoder(Encoder):
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def name(self):
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return 'ZLIB'
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def check(self, data):
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if not ReEncoder.Utils.isBinaryData(data):
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return False
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try:
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if zlib.compress(zlib.decompress(data)) == data:
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return True
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except:
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pass
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return False
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def encode(self, data):
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return zlib.compress(data)
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def decode(self, data):
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return zlib.decompress(data)
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# ============================================================
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# ENCODING DETECTION IMPLEMENTATION
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#
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MaxEncodingDepth = 20
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def __init__(self):
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self.encodings = []
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self.encoders = (
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ReEncoder.URLEncoder(),
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ReEncoder.HexEncoder(),
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ReEncoder.Base64Encoder(),
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ReEncoder.Base64URLSafeEncoder(),
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ReEncoder.JWTEncoder(),
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ReEncoder.ZlibEncoder(),
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# None must always be the last detector
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ReEncoder.NoneEncoder(),
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)
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self.encodersMap = {}
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self.data = ''
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self.preferredOutputFormat = ReEncoder.PREFER_AUTO
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for encoder in self.encoders:
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self.encodersMap[encoder.name()] = encoder
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@staticmethod
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def log(text):
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if ReEncoder.DEBUG:
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print(text)
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def verifyEncodings(self, encodings):
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for encoder in encodings:
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if type(encoder) == str:
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if not encoder in self.encodersMap.keys():
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raise Exception("Passed unknown encoder's name.")
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elif not issubclass(ReEncoder.Encoder, encoder):
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raise Exception("Passed encoder is of unknown type.")
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def generateEncodingTree(self, data):
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step = 0
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maxSteps = len(self.encoders) * ReEncoder.MaxEncodingDepth
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peeledBefore = 0
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peeledOff = 0
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currData = data
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while step < maxSteps:
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peeledBefore = peeledOff
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for encoder in self.encoders:
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step += 1
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ReEncoder.log('[.] Trying: {} (peeled off: {}). Current form: "{}"'.format(encoder.name(), peeledOff, currData))
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if encoder.check(currData):
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if encoder.name() == 'None':
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continue
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if encoder.name().lower().startswith('base64') and (len(currData) % 4 == 0):
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ReEncoder.log('[.] Unclear situation whether input ({}) is Base64 encoded. Branching.'.format(
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currData
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))
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yield ('None', currData, True)
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if encoder.name().lower().startswith('hex') and (len(currData) % 2 == 0):
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ReEncoder.log('[.] Unclear situation whether input ({}) is Hex encoded. Branching.'.format(
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currData
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))
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yield ('None', currData, True)
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ReEncoder.log('[+] Detected encoder: {}'.format(encoder.name()))
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currData = encoder.decode(currData)
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yield (encoder.name(), currData, False)
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peeledOff += 1
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break
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if (peeledOff - peeledBefore) == 0:
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break
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def formEncodingCandidates(self, root):
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iters = [[node for node in children] for children in anytree.LevelOrderGroupIter(root)]
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candidates = []
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for node in iters[-1]:
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name = node.name
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decoded = node.decoded
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ReEncoder.log('[.] Candidate for best decode using {}: "{}"...'.format(
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name, decoded[:20]
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))
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candidates.append([name, decoded, 0.0])
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return candidates
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@staticmethod
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def entropy(data, unit='natural'):
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base = {
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'shannon' : 2.,
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'natural' : math.exp(1),
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'hartley' : 10.
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}
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if len(data) <= 1:
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return 0
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counts = Counter()
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for d in data:
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counts[d] += 1
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probs = [float(c) / len(data) for c in counts.values()]
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probs = [p for p in probs if p > 0.]
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ent = 0
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for p in probs:
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if p > 0.:
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ent -= p * math.log(p, base[unit])
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return ent
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def evaluateEncodingTree(self, root):
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(printableEncodings, printableCandidate) = self.evaluateEncodingTreePicker(root, False)
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(binaryEncodings, binaryCandidate) = self.evaluateEncodingTreePicker(root, True)
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if self.preferredOutputFormat == ReEncoder.PREFER_TEXT:
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ReEncoder.log('Returning text/printable output format as requested preferred one.')
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return printableEncodings
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elif self.preferredOutputFormat == ReEncoder.PREFER_BINARY:
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ReEncoder.log('Returning binary output format as requested preferred one.')
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return binaryEncodings
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else:
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ReEncoder.log('Trying to determine preferred output format...')
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ReEncoder.log('\n---------------------------------------')
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ReEncoder.log('[>] Winning printable encoding path scored: {} points.'.format(
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printableCandidate[2]
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))
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ReEncoder.log('[>] Winning binary encoding path scored: {} points.'.format(
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binaryCandidate[2]
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))
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if(printableCandidate[2] >= binaryCandidate[2]):
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ReEncoder.log('\n[+] Choosing all-time winner: PRINTABLE output format.')
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return printableEncodings
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ReEncoder.log('\n[+] Choosing all-time winner: BINARY output format.')
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ReEncoder.log('---------------------------------------\n')
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return binaryEncodings
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def evaluateEncodingTreePicker(self, root, preferBinary):
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candidates = self._evaluateEncodingTreeWorker(root, preferBinary)
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maxCandidate = 0
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for i in range(len(candidates)):
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candidate = candidates[i]
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name = candidate[0]
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decoded = candidate[1]
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points = float(candidate[2])
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if points > candidates[maxCandidate][2]:
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maxCandidate = i
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winningCandidate = candidates[maxCandidate]
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winningPaths = anytree.search.findall_by_attr(
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root,
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name = 'decoded',
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value = winningCandidate[1]
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)
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ReEncoder.log('[?] Other equally good candidate paths:\n' + str(winningPaths))
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winningPath = winningPaths[0]
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preferred = 'printable'
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if preferBinary:
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preferred = 'binary'
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ReEncoder.log('[+] Winning decode path for {} output is:\n{}'.format(
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preferred,
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str(winningPath))
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)
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encodings = [x.name for x in winningPath.path if x != 'None']
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return (encodings, winningCandidate)
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def _evaluateEncodingTreeWorker(self, root, preferBinary = False):
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weights = {
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'unreadableChars' : 0.0,
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'printableChars' : 9.6,
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'entropyScore' : 4.0,
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'length' : 1.0,
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}
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if preferBinary:
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weights['unreadableChars'] = 24.0
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weights['printableChars'] = 0.0
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weights['entropyScore'] = 2.666667
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candidates = self.formEncodingCandidates(root)
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for i in range(len(candidates)):
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candidate = candidates[i]
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name = candidate[0]
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decoded = candidate[1]
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points = float(candidate[2])
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entropy = ReEncoder.entropy(decoded)
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printables = sum([int(x in string.printable) for x in decoded])
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nonprintables = len(decoded) - printables
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ReEncoder.log('[=] Evaluating candidate: {} (entropy: {}, data: "{}")'.format(
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name, entropy, decoded
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))
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# Step 1: Adding points for printable percentage.
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printablePoints = float(weights['printableChars']) * (float(printables) / float(len(decoded)))
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nonPrintablePoints = float(weights['unreadableChars']) * (float(nonprintables) / float(len(decoded)))
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# Step 2: If encoder is Base64 and was previously None
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# - then length and entropy of previous values should be of slighly lower weights
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if name.lower() == 'none' \
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and len(candidates) > i+1 \
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and candidates[i+1][0].lower().startswith('base64'):
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ReEncoder.log('\tAdding fine for being base64')
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entropyPoints = entropy * (weights['entropyScore'] * 0.666666)
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lengthPoints = float(len(decoded)) * (weights['length'] * 0.666666)
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else:
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entropyPoints = entropy * weights['entropyScore']
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lengthPoints = float(len(decoded)) * weights['length']
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if printables > nonprintables:
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ReEncoder.log('More printable chars than binary ones.')
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ReEncoder.log('\tAdding {} points for printable entropy.'.format(entropyPoints))
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ReEncoder.log('\tAdding {} points for printable characters.'.format(printablePoints))
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points += printablePoints
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else:
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ReEncoder.log('More binary chars than printable ones.')
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ReEncoder.log('\tAdding {} points for binary entropy.'.format(entropyPoints))
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ReEncoder.log('\tAdding {} points for binary characters.'.format(nonPrintablePoints))
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points += nonPrintablePoints
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points += entropyPoints
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# Step 4: Add points for length
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ReEncoder.log('\tAdding {} points for length.'.format(lengthPoints))
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points += lengthPoints
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ReEncoder.log('\tScored in total: {} points.'.format(points))
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candidates[i][2] = points
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return candidates
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def getWinningDecodePath(self, root):
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return [x for x in self.evaluateEncodingTree(root) if x != 'None']
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def process(self, data):
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root = anytree.Node('None', decoded = data)
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prev = root
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for (name, curr, branch) in self.generateEncodingTree(data):
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ReEncoder.log('[*] Generator returned: ("{}", "{}", {})'.format(
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name, curr[:20], str(branch)
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))
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currNode = anytree.Node(name, parent = prev, decoded = curr)
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if branch:
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pass
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else:
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prev = currNode
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for pre, fill, node in anytree.RenderTree(root):
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if node.name != 'None':
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ReEncoder.log("%s%s (%s)" % (pre, node.name, node.decoded[:20].decode('ascii', 'ignore')))
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self.encodings = self.getWinningDecodePath(root)
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ReEncoder.log('[+] Selected encodings: {}'.format(str(self.encodings)))
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def decode(self, data, preferredOutputFormat = PREFER_AUTO, encodings = []):
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self.preferredOutputFormat = preferredOutputFormat
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if preferredOutputFormat != ReEncoder.PREFER_AUTO and \
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preferredOutputFormat != ReEncoder.PREFER_TEXT and \
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preferredOutputFormat != ReEncoder.PREFER_BINARY:
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raise Exception('Unknown preferred output format specified in decode(): {}'.format(
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preferredOutputFormat
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))
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if not encodings:
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self.process(data)
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else:
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self.verifyEncodings(encodings)
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self.encodings = encodings
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for encoderName in self.encodings:
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d = self.encodersMap[encoderName].decode(data)
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data = d
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return data
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def encode(self, data, encodings = []):
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if encodings:
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encodings.reverse()
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self.verifyEncodings(encodings)
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self.encodings = encodings
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for encoderName in self.encodings[::-1]:
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e = self.encodersMap[encoderName].encode(data)
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data = e
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return data
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def main(argv):
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# Sample 1: ZLIB -> Base64 -> URLEncode
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sample = 'eJzzSM3JyVcozy%2FKSVFIK8rPVQhKdc1Lzk9JLVIEAIr8Cck%3D'
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# Sample 2: URLEncode -> Base64 -> HexEncode
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#sample = '4a5451344a5459314a545a6a4a545a6a4a545a6d4a5449774a5463334a545a6d4a5463794a545a6a4a5459304a5449784a5449774a544e684a544a6b4a544935'
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if len(argv) != 2:
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print('Usage: reencode.py <text|file>')
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print('Using sample: "{}"'.format(sample))
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text = sample
|
|
else:
|
|
text = argv[1]
|
|
|
|
if os.path.isfile(text):
|
|
f = open(text, 'rb')
|
|
text = f.read()
|
|
f.close()
|
|
|
|
decoder = ReEncoder()
|
|
decoded = decoder.decode(text)
|
|
|
|
print('(1) DECODED TEXT: "{}"'.format(decoded))
|
|
|
|
decoded = 'FOO ' + decoded + ' BAR'
|
|
|
|
print('\n(2) TO BE ENCODED TEXT: "{}"'.format(decoded))
|
|
|
|
decoded = decoder.encode(decoded)
|
|
print('(3) ENCODED FORM: "{}"'.format(decoded))
|
|
|
|
if __name__ == '__main__':
|
|
main(sys.argv)
|