mirror of
https://github.com/apprenticeharper/DeDRM_tools
synced 2024-12-27 09:58:59 +01:00
311 lines
9.2 KiB
Python
311 lines
9.2 KiB
Python
#!/usr/bin/env python3
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# -*- coding: utf-8 -*-
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# kgenpids.py
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# Copyright © 2008-2020 Apprentice Harper et al.
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__license__ = 'GPL v3'
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__version__ = '3.0'
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# Revision history:
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# 2.0 - Fix for non-ascii Windows user names
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# 2.1 - Actual fix for non-ascii WIndows user names.
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# 2.2 - Return information needed for KFX decryption
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# 3.0 - Python 3 for calibre 5.0
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import sys
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import os, csv
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import binascii
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import zlib
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import re
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from struct import pack, unpack, unpack_from
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import traceback
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class DrmException(Exception):
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pass
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global charMap1
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global charMap3
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global charMap4
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charMap1 = b'n5Pr6St7Uv8Wx9YzAb0Cd1Ef2Gh3Jk4M'
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charMap3 = b'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/'
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charMap4 = b'ABCDEFGHIJKLMNPQRSTUVWXYZ123456789'
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# crypto digestroutines
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import hashlib
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def MD5(message):
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ctx = hashlib.md5()
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ctx.update(message)
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return ctx.digest()
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def SHA1(message):
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ctx = hashlib.sha1()
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ctx.update(message)
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return ctx.digest()
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# Encode the bytes in data with the characters in map
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# data and map should be byte arrays
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def encode(data, map):
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result = b''
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for char in data:
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value = char
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Q = (value ^ 0x80) // len(map)
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R = value % len(map)
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result += bytes([map[Q]])
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result += bytes([map[R]])
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return result
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# Hash the bytes in data and then encode the digest with the characters in map
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def encodeHash(data,map):
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return encode(MD5(data),map)
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# Decode the string in data with the characters in map. Returns the decoded bytes
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def decode(data,map):
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result = ''
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for i in range (0,len(data)-1,2):
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high = map.find(data[i])
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low = map.find(data[i+1])
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if (high == -1) or (low == -1) :
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break
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value = (((high * len(map)) ^ 0x80) & 0xFF) + low
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result += pack('B',value)
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return result
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#
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# PID generation routines
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#
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# Returns two bit at offset from a bit field
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def getTwoBitsFromBitField(bitField,offset):
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byteNumber = offset // 4
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bitPosition = 6 - 2*(offset % 4)
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return bitField[byteNumber] >> bitPosition & 3
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# Returns the six bits at offset from a bit field
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def getSixBitsFromBitField(bitField,offset):
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offset *= 3
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value = (getTwoBitsFromBitField(bitField,offset) <<4) + (getTwoBitsFromBitField(bitField,offset+1) << 2) +getTwoBitsFromBitField(bitField,offset+2)
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return value
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# 8 bits to six bits encoding from hash to generate PID string
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def encodePID(hash):
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global charMap3
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PID = b''
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for position in range (0,8):
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PID += bytes([charMap3[getSixBitsFromBitField(hash,position)]])
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return PID
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# Encryption table used to generate the device PID
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def generatePidEncryptionTable() :
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table = []
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for counter1 in range (0,0x100):
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value = counter1
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for counter2 in range (0,8):
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if (value & 1 == 0) :
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value = value >> 1
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else :
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value = value >> 1
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value = value ^ 0xEDB88320
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table.append(value)
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return table
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# Seed value used to generate the device PID
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def generatePidSeed(table,dsn) :
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value = 0
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for counter in range (0,4) :
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index = (dsn[counter] ^ value) & 0xFF
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value = (value >> 8) ^ table[index]
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return value
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# Generate the device PID
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def generateDevicePID(table,dsn,nbRoll):
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global charMap4
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seed = generatePidSeed(table,dsn)
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pidAscii = b''
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pid = [(seed >>24) &0xFF,(seed >> 16) &0xff,(seed >> 8) &0xFF,(seed) & 0xFF,(seed>>24) & 0xFF,(seed >> 16) &0xff,(seed >> 8) &0xFF,(seed) & 0xFF]
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index = 0
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for counter in range (0,nbRoll):
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pid[index] = pid[index] ^ dsn[counter]
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index = (index+1) %8
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for counter in range (0,8):
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index = ((((pid[counter] >>5) & 3) ^ pid[counter]) & 0x1f) + (pid[counter] >> 7)
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pidAscii += bytes([charMap4[index]])
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return pidAscii
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def crc32(s):
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return (~binascii.crc32(s,-1))&0xFFFFFFFF
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# convert from 8 digit PID to 10 digit PID with checksum
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def checksumPid(s):
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global charMap4
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crc = crc32(s)
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crc = crc ^ (crc >> 16)
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res = s
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l = len(charMap4)
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for i in (0,1):
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b = crc & 0xff
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pos = (b // l) ^ (b % l)
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res += bytes([charMap4[pos%l]])
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crc >>= 8
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return res
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# old kindle serial number to fixed pid
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def pidFromSerial(s, l):
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global charMap4
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crc = crc32(s)
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arr1 = [0]*l
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for i in range(len(s)):
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arr1[i%l] ^= s[i]
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crc_bytes = [crc >> 24 & 0xff, crc >> 16 & 0xff, crc >> 8 & 0xff, crc & 0xff]
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for i in range(l):
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arr1[i] ^= crc_bytes[i&3]
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pid = b""
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for i in range(l):
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b = arr1[i] & 0xff
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pid += bytes([charMap4[(b >> 7) + ((b >> 5 & 3) ^ (b & 0x1f))]])
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return pid
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# Parse the EXTH header records and use the Kindle serial number to calculate the book pid.
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def getKindlePids(rec209, token, serialnum):
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if isinstance(serialnum,str):
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serialnum = serialnum.encode('utf-8')
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if rec209 is None:
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return [serialnum]
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pids=[]
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# Compute book PID
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pidHash = SHA1(serialnum+rec209+token)
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bookPID = encodePID(pidHash)
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bookPID = checksumPid(bookPID)
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pids.append(bookPID)
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# compute fixed pid for old pre 2.5 firmware update pid as well
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kindlePID = pidFromSerial(serialnum, 7) + b"*"
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kindlePID = checksumPid(kindlePID)
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pids.append(kindlePID)
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return pids
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# parse the Kindleinfo file to calculate the book pid.
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keynames = ['kindle.account.tokens','kindle.cookie.item','eulaVersionAccepted','login_date','kindle.token.item','login','kindle.key.item','kindle.name.info','kindle.device.info', 'MazamaRandomNumber']
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def getK4Pids(rec209, token, kindleDatabase):
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global charMap1
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pids = []
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try:
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# Get the kindle account token, if present
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kindleAccountToken = bytearray.fromhex((kindleDatabase[1])['kindle.account.tokens'])
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except KeyError:
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kindleAccountToken=""
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pass
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try:
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# Get the DSN token, if present
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DSN = bytearray.fromhex((kindleDatabase[1])['DSN'])
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print("Got DSN key from database {0}".format(kindleDatabase[0]))
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except KeyError:
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# See if we have the info to generate the DSN
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try:
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# Get the Mazama Random number
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MazamaRandomNumber = bytearray.fromhex((kindleDatabase[1])['MazamaRandomNumber'])
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#print "Got MazamaRandomNumber from database {0}".format(kindleDatabase[0])
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try:
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# Get the SerialNumber token, if present
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IDString = bytearray.fromhex((kindleDatabase[1])['SerialNumber'])
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print("Got SerialNumber from database {0}".format(kindleDatabase[0]))
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except KeyError:
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# Get the IDString we added
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IDString = bytearray.fromhex((kindleDatabase[1])['IDString'])
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try:
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# Get the UsernameHash token, if present
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encodedUsername = bytearray.fromhex((kindleDatabase[1])['UsernameHash'])
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print("Got UsernameHash from database {0}".format(kindleDatabase[0]))
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except KeyError:
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# Get the UserName we added
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UserName = bytearray.fromhex((kindleDatabase[1])['UserName'])
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# encode it
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encodedUsername = encodeHash(UserName,charMap1)
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#print "encodedUsername",encodedUsername.encode('hex')
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except KeyError:
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print("Keys not found in the database {0}.".format(kindleDatabase[0]))
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return pids
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# Get the ID string used
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encodedIDString = encodeHash(IDString,charMap1)
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#print "encodedIDString",encodedIDString.encode('hex')
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# concat, hash and encode to calculate the DSN
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DSN = encode(SHA1(MazamaRandomNumber+encodedIDString+encodedUsername),charMap1)
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#print "DSN",DSN.encode('hex')
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pass
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if rec209 is None:
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pids.append(DSN+kindleAccountToken)
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return pids
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# Compute the device PID (for which I can tell, is used for nothing).
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table = generatePidEncryptionTable()
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devicePID = generateDevicePID(table,DSN,4)
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devicePID = checksumPid(devicePID)
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pids.append(devicePID)
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# Compute book PIDs
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# book pid
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pidHash = SHA1(DSN+kindleAccountToken+rec209+token)
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bookPID = encodePID(pidHash)
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bookPID = checksumPid(bookPID)
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pids.append(bookPID)
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# variant 1
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pidHash = SHA1(kindleAccountToken+rec209+token)
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bookPID = encodePID(pidHash)
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bookPID = checksumPid(bookPID)
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pids.append(bookPID)
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# variant 2
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pidHash = SHA1(DSN+rec209+token)
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bookPID = encodePID(pidHash)
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bookPID = checksumPid(bookPID)
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pids.append(bookPID)
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return pids
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def getPidList(md1, md2, serials=[], kDatabases=[]):
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pidlst = []
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if kDatabases is None:
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kDatabases = []
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if serials is None:
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serials = []
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for kDatabase in kDatabases:
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try:
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pidlst.extend(map(bytes,getK4Pids(md1, md2, kDatabase)))
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except Exception as e:
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print("Error getting PIDs from database {0}: {1}".format(kDatabase[0],e.args[0]))
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traceback.print_exc()
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for serialnum in serials:
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try:
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pidlst.extend(map(bytes,getKindlePids(md1, md2, serialnum)))
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except Exception as e:
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print("Error getting PIDs from serial number {0}: {1}".format(serialnum ,e.args[0]))
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traceback.print_exc()
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return pidlst
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