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608 lines
24 KiB
Plaintext
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Inside Windows Product Activation
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A Fully Licensed Paper
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July 2001
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Fully Licensed GmbH, Rudower Chaussee 29, 12489 Berlin, Germany
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http://www.licenturion.com
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>> INTRODUCTION
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The current public discussion of Windows Product Activation (WPA) is
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characterized by uncertainty and speculation. In this paper we supply
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the technical details of WPA - as implemented in Windows XP - that
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Microsoft should have published long ago.
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While we strongly believe that every software vendor has the right to
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enforce the licensing terms governing the use of a piece of licensed
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software by technical means, we also do believe that each individual
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has the right to detailed knowledge about the full implications of the
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employed means and possible limitations imposed by it on software
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usage.
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In this paper we answer what we think are currently the two most
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important open questions related to Windows Product Activation.
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* Exactly what information is transmitted during activation?
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* How do hardware modifications affect an already activated
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installation of Windows XP?
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Our answers to these questions are based on Windows XP Release
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Candidate 1 (build 2505). Later builds as well as the final version of
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Windows XP might differ from build 2505, e.g. in the employed
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cryptographic keys or the layout of some of the data
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structures.
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However, beyond such minor modifications we expect Microsoft to cling
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to the general architecture of their activation mechanism. Thus, we
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are convinced that the answers provided by this paper will still be
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useful when the final version of Windows XP ships.
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This paper supplies in-depth technical information about the inner
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workings of WPA. Still, the discussion is a little vague at some
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points in order not to facilitate the task of an attacker attempting
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to circumvent the license enforcement supplied by the activation
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mechanism.
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XPDec, a command line utility suitable for verifying the presented
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information, can be obtained from http://www.licenturion.com/xp/. It
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implements the algorithms presented in this paper. Reading its source
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code, which is available from the same location, is highly
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recommended.
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We have removed an important cryptographic key from the XPDec source
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code. Recompiling the source code will thus fail to produce a working
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executable. The XPDec executable on our website, however, contains
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this key and is fully functional.
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So, download the source code to learn about the inner workings of WPA,
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but obtain the executable to experiment with your installation of
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Windows XP.
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We expect the reader to be familiar with the general procedure of
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Windows Product Activation.
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>> INSIDE THE INSTALLATION ID
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We focused our research on product activation via telephone. We did
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so, because we expected this variant of activation to be the most
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straight-forward to analyze.
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The first step in activating Windows XP via telephone is supplying the
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call-center agent with the Installation ID displayed by msoobe.exe,
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the application that guides a user through the activation process. The
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Installation ID is a number consisting of 50 decimal digits that are
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divided into groups of six digits each, as in
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002666-077894-484890-114573-XXXXXX-XXXXXX-XXXXXX-XXXXXX-XX
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In this authentic Installation ID we have substituted digits that we
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prefer not to disclose by 'X' characters.
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If msoobe.exe is invoked more than once, it provides a different
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Installation ID each time.
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In return, the call-center agent provides a Confirmation ID matching
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the given Installation ID. Entering the Confirmation ID completes the
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activation process.
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Since the Installation ID is the only piece of information revealed
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during activation, the above question concerning the information
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transmitted during the activation process is equivalent to the
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question
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'How is the Installation ID generated?'
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To find an answer to this question, we trace back each digit of the
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Installation ID to its origins.
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>>> Check digits
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The rightmost digit in each of the groups is a check digit to guard
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against simple errors such as the call center agent's mistyping of one
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of the digits read to him or her. The value of the check digit is
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calculated by adding the other five digits in the group, adding the
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digits at even positions a second time, and dividing the sum by
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seven. The remainder of the division is the value of the check
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digit. In the above example the check digit for the first group (6) is
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calculated as follows.
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1 | 2 | 3 | 4 | 5 <- position
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---+---+---+---+---
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0 | 0 | 2 | 6 | 6 <- digits
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0 + 0 + 2 + 6 + 6 = 14 (step 1: add all digits)
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0 + 6 + 14 = 20 (step 2: add even digits again)
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step 3: division
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20 / 7 = 2, remainder is 20 - (2 * 7) = 6
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=> check digit is 6
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Adding the even digits twice is probably intended to guard against the
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relatively frequent error of accidentally swapping two digits while
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typing, as in 00626 vs. 00266, which yield different check digits.
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>>> Decoding
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Removing the check digits results in a 41-digit decimal number. A
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decimal number of this length roughly corresponds to a 136-bit binary
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number. In fact, the 41-digit number is just the decimal encoding of
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such a 136-bit multi-precision integer, which is stored in little
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endian byte order as a byte array. Hence, the above Installation ID
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can also be represented as a sequence of 17 bytes as in
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0xXX 0xXX 0xXX 0xXX 0xXX 0xXX 0xXX 0xXX
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0x94 0xAA 0x46 0xD6 0x0F 0xBD 0x2C 0xC8
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0x00
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In this representation of the above Installation ID 'X' characters
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again substitute the digits that we prefer not to disclose. The '0x'
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prefix denotes hex notation throughout this paper.
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>>> Decryption
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When decoding arbitrary Installation IDs it can be noticed that the
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most significant byte always seems to be 0x00 or 0x01, whereas the
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other bytes look random. The reason for this is that the lower 16
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bytes of the Installation ID are encrypted, whereas the most
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significant byte is kept in plaintext.
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The cryptographic algorithm employed to encrypt the Installation ID is
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a proprietary four-round Feistel cipher. Since the block of input
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bytes passed to a Feistel cipher is divided into two blocks of equal
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size, this class of ciphers is typically applied to input blocks
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consisting of an even number of bytes - in this case the lower 16 of
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the 17 input bytes. The round function of the cipher is the SHA-1
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message digest algorithm keyed with a four-byte sequence.
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Let + denote the concatenation of two byte sequences, ^ the XOR
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operation, L and R the left and right eight-byte input half for one
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round, L' and R' the output halves of said round, and First-8() a
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function that returns the first eight bytes of an SHA-1 message
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digest. Then one round of decryption looks as follows.
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L' = R ^ First-8(SHA-1(L + Key))
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R' = L
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The result of the decryption is 16 bytes of plaintext, which are -
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together with the 17th unencrypted byte - from now on interpreted as
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four double words in little endian byte order followed by a single
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byte as in
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name | size | offset
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-----+-------------+-------
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H1 | double word | 0
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H2 | double word | 4
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P1 | double word | 8
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P2 | double word | 12
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P3 | byte | 16
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H1 and H2 specify the hardware configuration that the Installation ID
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is linked to. P1 and P2 as well as the remaining byte P3 contain the
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Product ID associated with the Installation ID.
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>>> Product ID
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The Product ID consists of five groups of decimal digits, as in
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AAAAA-BBB-CCCCCCC-DDEEE
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If you search your registry for a value named 'ProductID', you will
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discover the ID that applies to your installation. The 'About' window
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of Internet Explorer should also yield your Product ID.
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>>>> Decoding
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The mapping between the Product ID in decimal representation and its
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binary encoding in the double words P1 and P2 and the byte P3 is
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summarized in the following table.
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digits | length | encoding
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--------+---------+---------------------------------------
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AAAAA | 17 bits | bit 0 to bit 16 of P1
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BBB | 10 bits | bit 17 to bit 26 of P1
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CCCCCCC | 28 bits | bit 27 to bit 31 of P1 (lower 5 bits)
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| | bit 0 to bit 22 of P2 (upper 23 bits)
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DDEEE | 17 bits | bit 23 to bit 31 of P2 (lower 9 bits)
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| | bit 0 to bit 7 of P3 (upper 8 bits)
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The meaning of each of the five groups of digits is documented in the
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next table.
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digits | meaning
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--------+-------------------------------------------------
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AAAAA | apparently always 55034 (in Windows XP RC1)
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BBB | most significant three digits of Raw Product Key
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| (see below)
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CCCCCCC | least significant six digits of Raw Product Key
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| plus check digit (see below)
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DD | index of the public key used to verify the
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| Product Key (see below)
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EEE | random value
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As can be seen, the (Raw) Product Key plays an important role in
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generating the Product ID.
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>>>> Product Key
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The Raw Product Key is buried inside the Product Key that is printed
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on the sticker distributed with each Windows XP CD. It consists of
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five alphanumeric strings separated by '-' characters, where each
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string is composed of five characters, as in
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FFFFF-GGGGG-HHHHH-JJJJJ-KKKKK
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Each character is one of the following 24 letters and digits:
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B C D F G H J K M P Q R T V W X Y 2 3 4 6 7 8 9
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Very similar to the decimal encoding of the Installation ID the 25
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characters of the Product Key form a base-24 encoding of the binary
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representation of the Product Key. Decoding the Product Key yields a
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multi-precision integer of roughly 115 bits, which is stored - again
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in little endian byte order - in an array of 15 bytes. Decoding the
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above Product Key results in the following byte sequence.
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0x6F 0xFA 0x95 0x45 0xFC 0x75 0xB5 0x52
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0xBB 0xEF 0xB1 0x17 0xDA 0xCD 0x00
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Of these 15 bytes the least significant four bytes contain the Raw
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Product Key in little endian byte order. The least significant bit is
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removed by shifting this 32-bit value (0x4595FA6F - remember the
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little endian byte order) to the left by one bit position, resulting
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in a Raw Product Key of 0x22CAFD37, or
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583728439
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in decimal notation.
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The eleven remaining bytes form a digital signature, allowing
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verification of the authenticity of the Product Key by means of a
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hard-coded public key.
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>>>> Product Key -> Product ID
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The three most significant digits, i.e. 583, of the Raw Product Key's
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nine-digit decimal representation directly map to the BBB component of
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the Product ID described above.
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To obtain the CCCCCCC component, a check digit is appended to the
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remaining six digits 728439. The check digit is chosen such that the
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sum of all digits - including the check digit - is divisible by
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seven. In the given case, the sum of the six digits is
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7 + 2 + 8 + 4 + 3 + 9 = 33
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which results in a check digit of 2, since
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7 + 2 + 8 + 4 + 3 + 9 + 2 = 33 + 2 = 35
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which is divisible by seven. The CCCCCCC component of the Product ID
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is therefore 7284392.
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For verifying a Product Key, more than one public key is available. If
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verification with the first public key fails, the second is tried,
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etc. The DD component of the Product ID specifies which of the public
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keys in this sequence was successfully used to verify the Product Key.
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This mechanism might be intended to support several different parties
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generating valid Product Keys with different individual private keys.
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However, the different private keys might also represent different
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versions of a product. A Product Key for the 'professional' release
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could then be signed with a different key than a Product Key for the
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'server' release. The DD component would then represent the product
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version.
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Finally, a valid Product ID derived from our example Product Key might
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be
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55034-583-7284392-00123
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which indicates that the first public key (DD = index = 0) matched and
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123 was chosen as the random number EEE.
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The randomly selected EEE component is the reason for msoobe.exe
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presenting a different Installation ID at each invocation. Because of
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the applied encryption this small change results in a completely
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different Installation ID.
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So, the Product ID transmitted during activation will most probably
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differ in the last three digits from your Product ID as displayed by
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Internet Explorer or as stored in the registry.
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>>> Hardware Information
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As discussed above, the hardware configuration linked to the
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Installation ID is represented by the two double words H1 and H2.
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>>>> Bit-fields
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For this purpose, the double words are divided into twelve
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bit-fields. The relationship between the computer hardware and the
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bit-fields is given in the following table.
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double word | offset | length | bit-field value based on
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------------+--------+--------+----------------------------
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H1 | 0 | 10 | volume serial number string
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| | | of system volume
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H1 | 10 | 10 | network adapter MAC address
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| | | string
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H1 | 20 | 7 | CD-ROM drive hardware
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| | | identification string
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H1 | 27 | 5 | graphics adapter hardware
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| | | identification string
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H2 | 0 | 3 | unused, set to 001
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H2 | 3 | 6 | CPU serial number string
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H2 | 9 | 7 | harddrive hardware
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| | | identification string
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H2 | 16 | 5 | SCSI host adapter hardware
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| | | identification string
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H2 | 21 | 4 | IDE controller hardware
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| | | identification string
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H2 | 25 | 3 | processor model string
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H2 | 28 | 3 | RAM size
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H2 | 31 | 1 | 1 = dockable
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| | | 0 = not dockable
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Bit 31 of H2 specifies, whether the bit-fields represent a notebook
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computer that supports a docking station. If docking is possible, the
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activation mechanism will be more tolerant with respect to future
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hardware modifications. Here, the idea is that plugging a notebook
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into its docking station possibly results in changes to its hardware
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configuration, e.g. a SCSI host adapter built into the docking station
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may become available.
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Bits 2 through 0 of H2 are unused and always set to 001.
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If the hardware component corresponding to one of the remaining ten
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bit-fields is present, the respective bit-field contains a non-zero
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value describing the component. A value of zero marks the hardware
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component as not present.
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All hardware components are identified by a hardware identification
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string obtained from the registry. Hashing this string provides the
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value for the corresponding bit-field.
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>>>> Hashing
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The hash result is obtained by feeding the hardware identification
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string into the MD5 message digest algorithm and picking the number of
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bits required for a bit-field from predetermined locations in the
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resulting message digest. Different predetermined locations are used
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for different bit-fields. In addition, a hash result of zero is
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avoided by calculating
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Hash = (Hash % BitFieldMax) + 1
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where BitFieldMax is the maximal value that may be stored in the
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bit-field in question, e.g. 1023 for a 10-bit bit-field, and 'x % y'
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denotes the remainder of the division of x by y. This results in
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values between 1 and BitFieldMax. The obtained value is then stored in
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the respective bit-field.
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>>>> RAM bit-field
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The bit-field related to the amount of RAM available to the operating
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system is calculated differently. The seven valid values specify the
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approximate amount of available RAM as documented in the following
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table.
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value | amount of RAM available
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------+---------------------------
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0 | (bit-field unused)
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1 | below 32 MB
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2 | between 32 MB and 63 MB
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3 | between 64 MB and 127 MB
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4 | between 128 MB and 255 MB
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5 | between 256 MB and 511 MB
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6 | between 512 MB and 1023 MB
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7 | above 1023 MB
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It is important to note that the amount of RAM is retrieved by calling
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the GlobalMemoryStatus() function, which reports a few hundred
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kilobytes less than the amount of RAM physically installed. So, 128 MB
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of RAM would typically be classified as "between 64 MB and 127 MB".
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>>>> Real-world example
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Let us have a look at a real-world example. On one of our test systems
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the hardware information consists of the following eight bytes.
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0xC5 0x95 0x12 0xAC 0x01 0x6E 0x2C 0x32
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Converting the bytes into H1 and H2, we obtain
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H1 = 0xAC1295C5 and H2 = 0x322C6E01
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Splitting H1 and H2 yields the next table in which we give the value
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of each of the bit-fields and the information from which each value is
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derived.
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dw & | |
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offset | value | derived from
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-------+-------+-----------------------------------------------
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H1 0 | 0x1C5 | '1234-ABCD'
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H1 10 | 0x0A5 | '00C0DF089E44'
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H1 20 | 0x37 | 'SCSI\CDROMPLEXTOR_CD-ROM_PX-32TS__1.01'
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H1 27 | 0x15 | 'PCI\VEN_102B&DEV_0519&SUBSYS_00000000&REV_01'
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H2 0 | 0x1 | (unused, always 0x1)
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H2 3 | 0x00 | (CPU serial number not present)
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H2 9 | 0x37 | 'SCSI\DISKIBM_____DCAS-34330______S65A'
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H2 16 | 0x0C | 'PCI\VEN_9004&DEV_7178&SUBSYS_00000000&REV_03'
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H2 21 | 0x1 | 'PCI\VEN_8086&DEV_7111&SUBSYS_00000000&REV_01'
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H2 25 | 0x1 | 'GenuineIntel Family 6 Model 3'
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H2 28 | 0x3 | (system has 128 MB of RAM)
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H2 31 | 0x0 | (system is not dockable)
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>>> Using XPDec
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XPDec is a utility to be run from the command prompt. It may be
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invoked with one of four command line options to carry out one of four
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tasks.
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>>>> XPDec -i
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This option enables you to access the information hidden in an
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Installation ID. It decodes the Installation ID, decrypts it, and
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displays the values of the hardware bit-fields as well as the Product
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ID of your product. Keep in mind that the last three digits of the
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Product ID contained in the Installation ID are randomly selected and
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differ from the Product ID displayed by Internet Explorer.
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The only argument needed for the '-i' option is the Installation ID,
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as in
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XPDec -i 002666-077894-484890-114573-XXXXXX-XXXXXX-XXXXXX-XXXXXX-XX
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>>>> XPDec -p
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To help you trace the origin of your Product ID, this option decodes a
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Product Key and displays the Raw Product Key as it would be used in a
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Product ID.
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The only argument needed for the '-p' option is the Product Key, as in
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XPDec -p FFFFF-GGGGG-HHHHH-JJJJJ-KKKKK
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Note that this option does not verify the digital signature of the
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Product Key.
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>>>> XPDec -v
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This option calculates the hash of a given volume serial number. It
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was implemented to illustrate our description of string hashing. First
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use '-i' to display the hardware bit-fields. Then use this option to
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verify our claims concerning the volume serial number hash.
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The only argument needed for the '-v' option is the volume serial
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number of your system volume, as in
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XPDec -v 1234-ABCD
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(The volume serial number is part of the 'dir' command's output.)
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>>>> XPDec -m
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This option calculates the network adapter bit-field value
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corresponding to the given MAC address. Similar to '-v' this option
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was implemented as a proof of concept.
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The only argument needed for the '-m' option is the MAC address of
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your network adapter, as in
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XPDec -m 00-C0-DF-08-9E-44
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(Use the 'route print' command to obtain the MAC address of your
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network adapter.)
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>> HARDWARE MODIFICATIONS
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When looking at the effects of hardware modifications on an already
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activated installation of Windows XP, the file 'wpa.dbl' in the
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'system32' directory plays a central role. It is a simple
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RC4-encrypted database that stores, among other things like expiration
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information and the Confirmation ID of an activated installation,
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a) the bit-field values representing the current hardware
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configuration,
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and
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b) the bit-field values representing the hardware configuration
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at the time of product activation.
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While a) is automatically updated each time the hardware configuration
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is modified in order to reflect the changes, b) remains fixed. Hence,
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b) can be thought of as a snapshot of the hardware configuration at
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the time of product activation.
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This snapshot does not exist in the database before product activation
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and if we compare the size of 'wpa.dbl' before and after activation,
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we will notice an increased file size. This is because the snapshot is
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added to the database.
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When judging whether re-activation is necessary, the bit-field values
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of a) are compared to the bit-field values of b), i.e. the current
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hardware configuration is compared to the hardware configuration at
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the time of activation.
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>>> Non-dockable computer
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Typically all bit-fields with the exception of the unused field and
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the 'dockable' field are compared. If more than three of these ten
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bit-fields have changed in a) since product activation, re-activation
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is required.
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This means, for example, that in our above real-world example, we
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could replace the harddrive and the CD-ROM drive and substantially
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upgrade our RAM without having to re-activate our Windows XP
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installation.
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However, if we completely re-installed Windows XP, the information in
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b) would be lost and we would have to re-activate our installation,
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even if we had not changed our hardware.
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>>> Dockable computer
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If bit 31 of H2 indicates that our computer supports a docking
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station, however, only seven of the ten bit-fields mentioned above are
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compared. The bit-fields corresponding to the SCSI host adapter, the
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IDE controller, and the graphics board are omitted. But again, of
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these remaining seven bit-fields, only up to three may change without
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requiring re-activation.
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>> CONCLUSIONS
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In this paper we have given a technical overview of Windows Product
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Activation as implemented in Windows XP. We have shown what
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information the data transmitted during product activation is derived
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from and how hardware upgrades affect an already activated
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installation.
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Looking at the technical details of WPA, we do not think that it is as
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problematic as many people have expected. We think so, because WPA is
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tolerant with respect to hardware modifications. In addition, it is
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likely that more than one hardware component map to a certain value
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for a given bit-field. From the above real-world example we know that
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the PX-32TS maps to the value 0x37 = 55. But there are probably many
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other CD-ROM drives that map to the same value. Hence, it is
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impossible to tell from the bit-field value whether it is a PX-32TS
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that we are using or one of the other drives that map to the same
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value.
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In contrast to many critics of Windows Product Activation, we think
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that WPA does not prevent typical hardware modifications and,
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moreover, respects the user's right to privacy.
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>> ABOUT THE AUTHORS
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Fully Licensed GmbH is a start-up company focusing on novel approaches
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to online software licensing and distribution. Have a look at their
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website at
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http://www.licenturion.com
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for more information.
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Their research branch every now and then analyzes licensing solutions
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implemented by other companies.
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>> COPYRIGHT
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Copyright (C) 2001 Fully Licensed GmbH (www.licenturion.com)
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All rights reserved.
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You are free to do whatever you want with this paper. However, you
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have to supply the URL of its online version
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http://www.licenturion.com/xp/
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with any work derived from this paper to give credit to its authors.
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