Milan Lukic on Sat, 28 Apr 2001 19:50:41 +0200 (CEST)


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[Nettime-bold] Re: <nettime> Lessons from the SDMI Challenge


hey
FLX!
tHnX 4 the material! 
g e a r w h o r e

reprazent! reprazent! reprazent! reprazent! reprazent! reprazent! reprazent!
reprazent! reprazent! reprazent! reprazent! reprazent! reprazent! reprazent!
reprazent! reprazent! reprazent! reprazent! reprazent! reprazent! reprazent!
reprazent! reprazent! reprazent! reprazent! reprazent! reprazent! reprazent!
 
 
 
 ----- Original Message -----
From: "Felix Stalder" <
stalder@fis.utoronto.ca>
To: <
nettime-l@bbs.thing.net>
Sent: Saturday, April 28, 2001 5:43 PM
Subject: <nettime> Lessons from the SDMI Challenge


>
> [Context: SDMI (Secure Digital Music Initiative [http://www.sdmi.org])
> issued a public challenge to break their watermarking technology intended
> to protect copyrights of digital music files. Some academics took up the
> challenge and broke the code. Now SDMI and RIAA (Recording Industry
> Association of America) are trying to prevent the academics from
> publishing the results of the contest they created in the first place.
> Here some of the exchanges between the academics and the lawyers, as well
> as the contentious paper itself. To get all the figures, go to the source:
>
http://cryptome.org/sdmi-attack.htm ]
>
>
>
> 26 April 2001:
>
> Date: Thu, 26 Apr 2001 08:51:31 -0400
> From: "Edward W. Felten" <
felten@CS.Princeton.EDU>
> To:
sdmi-paper-info@CS.Princeton.EDU
> Subject: Reading Between the Lines: Lessons from the SDMI Challenge
>
> The following statement was read by Edward W. Felten today at the Fourth
> International Information Hiding Workshop, in Pittsburgh.
>
> ===============
>
> On behalf of the authors of the paper "Reading Between the Lines: Lessons
> from the SDMI Challenge," I am disappointed to tell you that we will not
be
> presenting our paper today.
>
> Our paper was submitted via the normal academic peer-review process. The
> reviewers, who were chosen for their scientific reputations and
> credentials, enthusiastically recommended the paper for publication, due
to
> their judgment of the paper's scientific merit.
>
> Nevertheless, the Recording Industry Association of America, the SDMI
> Foundation, and the Verance Corporation threatened to bring a lawsuit if
we
> proceeded with our presentation or the publication of our paper. Threats
> were made against the authors, against the conference organizers, and
> against their respective employers.
>
> Litigation is costly, time-consuming, and uncertain, regardless of the
> merits of the other side's case. Ultimately we, the authors, reached a
> collective decision not to expose ourselves, our employers, and the
> conference organizers to litigation at this time.
>
> We remain committed to free speech and to the value of scientific debate
to
> our country and the world. We believe that people benefit from learning
the
> truth about the products they are asked to buy. We will continue to fight
> for these values, and for the right to publish our paper.
>
> We look forward to the day when we can present the results of our research
> to you, our colleagues, through the normal scientific publication process,
> so that you can judge our work for yourselves.
>
>
> --------------------------------------------------------
>
> 25 April 2001:
>
> Date: Wed, 25 Apr 2001 14:43:09 -0400 (EDT)
> From: Jeremy A Erwin <
jerwin@osf1.gmu.edu>
> To:
dvd-discuss@eon.law.harvard.edu
> Subject: [dvd-discuss] SDMI Challenge Information
>
> The Secure Internet Programming Laboratory
> (
http://www.cs.princeton.edu/sip/)
> posted this on their website
> (
http://www.cs.princeton.edu/sip/sdmi/)
>
> Update: Wednesday April 25, 2001, 1:30 PM EDT
>
> No decision has yet been announced regarding whether our presentation at
> the Pittsburgh conference will go ahead. The presentation is scheduled for
> 10:00 AM on Thursday. We will post any updated information here, as it
> becomes available. We have created a mailing list for people who are
> interested in receiving any announcements relating to the status of our
> paper and presentation. To subscribe, send email to
>
majordomo@cs.princeton.edu; the message body should contain the line
> "subscribe sdmi-paper-info".
>
>
> 20 April 2001. Thanks to Anonymous
>
> ------------------------------------------------------------------------
>
> [Letter, 3 pp.]
>
> MATTHEW J. OPPENHEIM, ESQ.
> Address illegible
>
> RIAA
>
>
> April 9, 2001
>
> Professor Edward Felten
> Department of Computer Science
> Princeton University
> Princeton, NJ 08544
>
> Dear Professor Felten,
>
> We understand that in conjunction with the 4th International Information
> Hiding Workshop to be held April 25-29, 2001, you and your colleagues who
> participated in last year's Secure Digital Music Initiative ("SDMI")
Public
> Challenge are planning to publicly release information concerning the
> technologies that were included in that challenge and certain methods you
> and your colleagues developed as part of your participation in the
> challenge. On behalf of the SDMI Foundation, I urge you to reconsider your
> intentions and to refrain from any public disclosure of confidential
> information derived from the Challenge and instead engage SDMI in a
> constructive dialogue on how the academic aspects of your research can be
> shared without jeopardizing the commercial interests of the owners of the
> various technologies.
>
> As you are aware, at least one of the technologies that was the subject of
> the Public Challenge, the Verance Watermark, is already in commercial use
> and the disclosure of any information that might assist others to remove
> this watermark would seriously jeopardize the technology and the content
it
> protects.1 Other technologies that were part of the Challenge are either
> likewise in commercial use or could be could be utilized in this capacity
> in the near future. Therefore, any disclosure of information that would
> allow the defeat of those technologies would violate both the spirit and
> the terms of the Click-Through Agreement (the "Agreement"). In addition,
> any disclosure of information gained from participating in the Public
> Challenge would be outside the scope of activities permitted by the
> Agreement and couldsubject you and your research team to actions under the
> Digital Millennium Copyright Act ("DCMA").
>
> ____________________
>
> 1 The Verance Watermark is currently used for DVD-Audio and SDMI Phase I
> products and certain portions of that technology are trade secrets.
>
>
> We appreciate your position, as articulated in the Frequently Asked
> Questions document, that the purpose of releasing your research is not
> designed to "help anyone impose or steal anything." Further more, you
> participation in the Challenge and your contemplated disclosure appears to
> be motivated by a desire to engage in scientific research that will ensure
> that SDMI does not deploy a flawed system. Unfortunately, the disclosure
> that you are contemplating could result in significantly broader
> consequences and could directly lead to the illegal distribution of
> copyrighted material. Such disclosure is not authorized in the Agreement,
> would constitute a violation of the Agreement and would subject your
> research team to enforcement actions under the DMCA and possibly other
> federal laws.
>
> As you are aware, the Agreement covering the Public challenge narrowly
> authorizes participants to attack the limited number of music samples and
> files that were provided by SDMI. The specific purpose of providing these
> encoded files and for setting up the Challenge was to assist SDMI in
> determining which of the proposed technologies are best suited to protect
> content in Phase II products. The limited waiver of rights (including
> possible DMCA claims) that was contained in the Agreement specifically
> prohibits participants from attacking content protected by SDMI
> technologies outside the Public Challenge. If your research is released to
> the public this is exactly what could occur. In short, you would be
> facilitating and encouraging the attack of copyrighted content outside the
> limited boundaries of the Public Challenge and thus places you and your
> researchers in direct violation of the Agreement.
>
> In addition, because public disclosure of your research would be outside
> the limited authorization of the Agreement, you could be subject to
> enforcement actions under federal law, including the DMCA. The Agreement
> specifically reserves any rights that proponents of the technology being
> attacked may have "under any applicable law, including, without
limitation,
> the U.S. Digital Millennium Copyright Act, for any acts not expressly
> authorized by their Agreement." The Agreement simply does not "expressly
> authorize" participants to disclose information and research developed
> through participating in the Public challenge and such disclosure could be
> the subject of a DMCA action.
>
> We recognize and appreciate your position, made clear throughout this
> process, that it is not your intention to engage in any illegal behavior
or
> to otherwise jeopardize the legitimate commercial interests of others. We
> are concerned that your actions are outside the peer review process
> established by the Public Challenge and setup by engineers and other
> experts to ensure the academic integrity of this project. With these facts
> in mind, we invite you to work with the SDMI Foundation to find a way for
> you to share the academic components of your research while remaining true
> to your intention to not violate the law or the Agreement. In the
meantime,
> we urge you to withdraw the paper submitted for the upcoming Information
> Hiding Workshop, assure that it is removed from the Workshop distribution
> materials and destroyed, and avoid a public discussion of confidential
> information.
>
> Sincerely,
>
> [Signature]
>
> Matthew Oppenheim, Secretary
> The SDMI Foundation
>
> cc: Mr. Ira S. Moskowitz, Program Chair, Information Hiding Workshop,
Naval
> Research Laboratory
> Cpt. Douglas S. Rau, USN, Commanding Officer, Naval Research Laboratory
> Mr. Howard Ende, General Counsel of Princeton
> Mr. Edward Dobkin, Computer Science Department Head of Princeton
>
> ------------------------------------------------------------------------
>
> [Paper, 15 pp.]
>
>
> Reading Between the Lines:
> Lessons from the SDMI Challenge
>
>
> Scott A. Craver1, John R McGregor1, Min Wu1, Bede Liu1,
> Adam Stubblefield2, Ben Swartzlander2, Dan S. Wallach2,
> Drew Dean3, and Edward W. Felten4
>
> 1 Dept. of Electrical Engineering, Princeton University
> 2 Dept. of Computer Science, Rice University
> 3 Computer Science Laboratory, Xerox Palo Alto Research Center
> 4 Dept. of Computer Science, Princeton University
>
> Abstract. The Secure Digital Music Initiative is a consortium of parties
> interested in preventing piracy of digital music, and to this end they are
> developing architectures for content protection on untrusted platforms.
> SDMI recently held a challenge to test the strength of 4 watermarking
> technologies, and 2 other security technologies. No documentation
explained
> the implementations of the technologies, and neither watermark embedding
> nor detecting software was directly accessible to challenge participants.
> We nevertheless accepted the challenge, and learned a great deal about the
> inner workings of the technologies. We report on our results here.
>
> 1 Introduction
>
> The Secure Digital Music Initiative (SDMI), a consortium of music-industry
> companies, is working to develop and standardize technologies that give
> music publishers more control over what consumers can do with recorded
> music that they buy. SDMI has been a somewhat secretive organization,
> releasing little information to the public about its goals, deliberations,
> and technology.
>
> In September 2000, SDMI announced a "public challenge" in which it invited
> members of the public to try to break certain data-encoding technologies
> that SDMI had developed [3]. The challenge offered a valuable window into
> SDMI, not only into its technologies but also into its plans and goals. We
> decided to use the challenge to learn as much as we could about SDMI. This
> paper is the result of our study.1 Section 2 presents an overview of the
> HackSDMI challenge. Section 3 analyzes the watermark challenges. Section 4
> analyzes the non-watermark challenges. Finally, we present our conclusions
> in section 5.
>
> ____________________
>
> 1 The SDMI challenge offered a small cash payment to be shared among
> everyone who broke at least one of the technologies and was willing to
sign
> a confidentiality agreement giving up all rights to discuss their
findings.
> The cash prize amounted to the price of a few days of time from a skilled
> computer security consultant, and it was to be split among all successful
> entrants, a group that we suspected might be significant in size. We chose
> to forgo the payment and retain our right to publish this paper.
>
>
> 2 The SDMI Challenge
>
> The SDMI challenge extended over roughly a three-week period, from
> September 15, 2000 until October 8, 2000. The challenge actually consisted
> of six sub-challenges, named with the letters A through F, each involving
a
> different technology developed by SDMI. We believe these challenges
> correspond to submissions to the SDMI's Call for Proposals for Phase II
> Screening Technology [4]. According to this proposal, the watermark's
> purpose is to restrict an audio clip which is compressed or has previously
> been compressed. That is, if the watermark is present an audio clip may
yet
> be admitted into an SDMI device, but only if it has not been degraded by
> compression. For each challenge, SDMI provided some information about how
a
> technology worked, and then challenged the public to create an object with
> a certain property. The exact information provided varied among the
> challenges. We note, though, that in all six cases SDMI provided less
> information than a music pirate would have access to in practice.
>
> 2.1 Watermark Challenges
>
> Four of the challenges (A, B, C, and F), involved watermarking
> technologies, in which subtle modifications are made to an audio file, to
> encode copyright control information without perceptible change in how the
> file sounds. Watermarks can be either robust or fragile. Robust watermarks
> are designed to survive common transformations like digital-to-audio
> conversion, compression and decompression, and the addition of small
> amounts of noise to the file. Fragile watermarks do not survive such
> transformations, and are used to indicate modification of the file. For
> each of the four watermark challenges, SDMI provided three files:
>
> - File 1: an unwatermarked song;
>
> - File 2: File 1, with a watermark added; and
>
> - File 3: another watermarked song.
>
> The challenge was to produce a file that sounded just like File 3 but did
> not have a watermark -- in other words, to remove the watermark from File
> 3.
>
> SDMI provided an on-line "oracle" for each challenge. Entrants could email
> a file to the oracle, and the oracle would tell them whether their
> submission satisfied the challenge, that is, whether it contained no
> detectable watermark while still sounding like File 3. Entrants were given
> no information about how watermark information was stored in the file or
> how the oracle detected watermarks, beyond the information that could be
> deduced from inspection of the three provided files.
>
> 2.2 Challenges D and E
>
> Challenge D concerned a technology designed to prevent a song from being
> separated from the album in which it was issued. Normally, every Compact
> Disc contains a table of contents, indicating the offsets and lengths of
> each audio track, followed by the audio data itself. Challenge D adds an
> "authenticator" track (approximately 50ms of very quiet audio,) a digital
> signature derived from the table of contents, which is supposed to be
> difficult to compute for an arbitrary CD. Challenge D is discussed in more
> detail in Section 4.1.
>
> Challenge E involved a technology similar to D, but one which would be
> immune the obvious attack on technology D, in which one compiled an
> unauthorized CD with the same table of contents as an authorized one, for
> which the authenticator track is given. Unfortunately, this challenge was
> constructed in a way that made it impossible to even start analyzing the
> technology. SDMI provided an oracle for this challenge, but unfortunately
> provided no music samples of any kind, so there was no way to determine
> what the oracle might be testing for.
>
> Given these facts, we decided not to analyze Challenge E. It is discussed
> briefly in Section 4.2.
>
> 3 The Watermarking Schemes
>
> In this section, we describe our attack(s) on each of the four watermark
> challenges (A,B,C,F). Our success was confirmed by emails received from
> SDMI's oracles.
>
>
>
> Fig. 1. The SDMI watermark attack problem. For each of the four watermark
> challenges, Sample-1, sample-2, and sample-3 are provided by SDMI sample-4
> is generated by participants in the challenge and submitted to SDMI oracle
> for testing.
>
> Figure 1 provides an overview of the challenge goal. As mentioned earlier,
> there are three audio files per watermark challenge: an original and
> watermarked version of one clip, and then a watermarked version of a
second
> clip, from which the mark is to be removed. All clips were 2 minutes long,
> sampled at 44.1kHz with 16-bit precision.
>
> The reader should note one serious flaw with this challenge arrangement.
> The goal is to remove a robust mark, while these proposals appear to be
> Phase II watermark screening technologies [4]. As we mentioned earlier, a
> Phase II screen is intended to reject audio clips if they have been
> compressed, and presumably compression degrades a fragile component of the
> watermark. An attacker need not remove the robust watermark to foil the
> Phase II screen, but could instead repair the modified fragile component
in
> compressed audio. This attack was not possible under the challenge setup.
>
> 3.1 Attack and Analysis of Technology A
>
> A reasonable first step in analyzing watermarked content with original,
> unmarked samples is differencing the original and marked versions in some
> way. Initially, we used sample-by-sample differences in order to determine
> roughly what kinds of watermark- ing methods were taking place.
> Unfortunately, technology A involved a slowly varying phase distortion
> which masked any other cues in a sample-by-sample difference. We
ultimately
> decided this distortion was a pre-processing separate from the watermark,
> in part because undoing the distortion alone did not foil the oracle.
>
> The phase distortion nevertheless led us to attempt an attack in which
both
> the phase and magnitude change between sample 1 and sample 2 is applied to
> sample 3. This attack was confirmed by SDMI's oracle as successful, and
> illustrates the general attack approach of imposing the difference in an
> original-watermark pair upon another media clip. Here, the "difference" is
> taken in the FFT domain rather than the time domain, based on our
> suspicions regarding the domain of embedding. Note that this attack did
not
> require much information about the watermarking scheme itself, and
> conversely did not provide much extra insight into its workings.
>
> A next step, then, is to compute the frequency response H(w) = W(w)/O(w)
of
> the watermarking process for segments of audio, and observe both |H(w)|
and
> the corresponding impulse response h(t). If the watermark is based on some
> kind of linear filter, whose properties change slowly enough relative to
> the size of a frame of samples, then this approach is ideal.
>
> Figure 2 illustrates one frequency response and impulse response about 0.3
> seconds into the music. These responses are based on FFTs of 882 samples,
> or one fiftieth second of music. As can be clearly seen, a pair of
> sinusoidal ripples are present within a certain frequency band,
> approximately 8-16Khz. Ripples in the frequency domain are indicative of
> echoes in the time domain, and a sum of sinusoids suggested the presence
of
> multiple echoes. The corresponding impulse response h(t) confirms this.
> This pattern of ripples changes quite rapidly from frame to frame.
>
> Thus, we had reason to suspect a complex echo hiding system, involving
> multiple time-varying echoes. It was at this point that we considered a
> patent search, knowing enough about the data hiding method that we could
> look for specific search terms, and we were pleased to discover that this
> particular scheme appears to be listed as an alternative embodiment in US
> patent number 05940135, awarded to Aris corporation, now part of Verance
> [5]. This provided us with little more detail than we had already
> discovered, but confirmed that we were on the right track, as well as
> providing the probable identity of the company which developed the scheme.
> It also spurred no small amount of discussion of the validity of
> Kerckhoffs's criterion, the driving principle in security that one must
not
> rely upon the obscurity of an algorithm. This is, surely, doubly true when
> the algorithm is patented.
>
>
>
> Fig. 2. A short-term complex echo. Above, the frequency response between
> the watermarked and original music, taken over 1/50 second, showing a
> sinusoidal ripple between 8 and 16 KHz. Below, the corresponding impulse
> response. The sinusoidal pattern in the frequency domain corresponds to a
> pair of echoes in the time domain.
>
> The most useful technical detail provided by the patent was that the
"delay
> hopping" pattern was likely discrete rather than continuous, allowing us
to
> search for appropriate frame sizes during which the echo parameters were
> constant. Data collection from the first second of audio showed a frame
> size of approximately 882 samples, or 1/50 second. We also observed that
> the mark did not begin until 10 frames after the start of the music, and
> that activity also existed in a band of lower frequency, approximately 4-8
> Khz. This could be the same echo obscured by other operations, or could be
> a second band used for another component in the watermarking scheme. A
very
> clear ripple in this band, indicating a single echo with a delay of about
> 34 samples, appears shortly before the main echo-hopping pattern begins.
>
> The next step in our analysis was the determination of the delay hopping
> pattern used in the watermarking method, as this appeared to be the
"secret
> key" of the data embedding scheme. It is reasonable to suspect that the
> pattern repeats itself in short order, since a watermark detector should
be
> able to find a mark in a subclip of music, without any assistance
initially
> aligning the mark with the detector's hopping pattern. Again, an analysis
> of the first second revealed a pattern of echo pairs that appeared to
> repeat every 16 frames, as outlined in figure 3. The delays appear to fall
> within six general categories, each delay approximately a multiple of 1/4
> millisecond. The exact values of the delays vary slightly, but this could
> be the result of the phase distortion present in the music.
>
>
>
> Fig. 3. The hypothesized delay hopping pattern of technology A. Here two
> stretches of 16 frames are illustrated side-by-side, with observed echoes
> in each frame categorized by six distinct delays: 2, 3, 4, 5, 6 or 7 times
> 0.00025 sec. Aside from several missing echoes, a pattern appears to
repeat
> every 16 frames. Note also that in each frame the echo gain is the same
for
> both echoes.
>
> The reader will also note that in apparently two frames there is only one
> echo. If this pattern were the union of two pseudorandom patterns chosen
> from six possible delay choices, two "collisions" would be within what is
> expected by chance.
>
> Next, there is the issue of the actual encoded bits. Further work shows
the
> sign of the echo gain does not repeat with the delay-hopping pattern, and
> so is likely at least part of an embedded message. Extracting such data
> without the help of an original can be problematic, although the patent,
of
> course, outlines numerous detector structors which can be used to this
end.
> We developed several tools for cepstral analysis to assist us in the
> process. See [2] for in introduction to cepstral analysis; Anderson and
> Petitcolas [1] illustrate its use in attacks on echo hiding watermark
> systems.
>
> With a rapidly changing delay, normal cepstral analysis does not seem a
> good choice. However, if we know that the same echo is likely to occur at
> multiples of 16/50 of a second, we can improve detector capability by
> combining the information of multiple liftered2 log spectra.
>
> ____________________
>
> 2 in accordance with the flopped vocabulary used with cepstral analysis,
> "liftering" refers to the process of filtering data in the frequency
domain
> rather than the time domain. Similarly, "quefrencies" are frequencies of
> ripples which occur in the frequency domain rather than the time domain.
>
>
> Three detector structures are shown in figure 4. In all three, a
collection
> of frames are selected for which the echo delays are believed to be the
> same. For each, the liftered log of an FFT or PSD of the frame is taken.
In
> the first two structures, we compute a cepstrum, for each frame, then
> either average their squared magnitudes, or simply their squares, in hopes
> that a spike of the appropriate quefrency will be clear in the
combination.
> The motivation for merely squaring the spectral coefficients comes from
the
> observation that a spike due to an echo will either possess a phase of
> theta or theta + pi for some value theta. Squaring without taking
> magnitudes can cause the echo phases to reinforce, whilst still permitting
> other elements to combine destructively.
>
>
>
> Fig. 4. Three cepstral detector structures. In each case we have a
> collection of distinct frames, each believed to possess echoes of the same
> delay. The first two compute cepstral data for each frame, and sum their
> squares (or squared magnitudes) to constructively combine the echo signal
> in all frames. The third structure illustrates a method for testing a
> hypothesized pattern of positive and negative gains, possibly useful for
> brute-forcing or testing for the presence of a known "ciphertext."
>
> In the final structure, one cepstrum. is taken using a guess of the gain
> sign for each suspect frame. With the correct guess, the ripple should be
> strongest, resulting in the largest spike from the cepstral detector.
> Figure 5 shows the output of this detector on several sets of suspect
> frames. While this requires an exponential amount of work for a given
> amount of frames, it has a different intended purpose: this is a
> brute-forcing tool, a utility for determining the most probable among a
set
> of suspected short strings of gain signs as an aid to extracting possible
> ciphertext values.
>
>
>
> Fig. 5. Detection of an echo. A screenshot of our CepstroMatic utility
> shows a combination of 4 separate frames of music, each a fiftieth of a
> second long, in which the same echo delay was believed to exist. Their
> combination shows a very clear ripple on the right, corresponding to a
> clear cepstral spike on the left. This is a single echo at a delay of 33
> samples, the delay suggested for these intervalus by the hypothesized
> delay-hopping pattern.
>
> Finally, there is the issue of what this embedded watermark means. Again,
> we are uncertain about a possible signalling band below 8Khz. This could
be
> a robust mark, signalling presence of a fragile mark of echoes between 8
> and 16 KHz. The 8-16KHz band does seem like an unusual place to hide
robust
> data, unless it does indeed extend further down, and so this could very
> easily be hidden information whose degredation is used to determine if
> music has already been compressed.
>
> Of course, knowledge of either the robust or fragile component of the mark
> is enough for an attacker to circumvent the scheme, because one can either
> remove the robust mark, or repair or reinstate the fragile mark after
> compression has damaged it. As mentioned earlier, this possible attack of
> repairing the fragile component appears to have been ruled out by the
> nature of the SDMI challenge oracles. One must wait and see if real-world
> attackers will attempt such an approach, or resort to more brute methods
or
> oracle attacks to remove the robust component.
>
> 3.2 Attack on Challenge B
>
> We analyzed samp1b.wav and samp2b.wav using short-time FFT. Shown in Fig.
6
> are the two FFT magnitudes for 1000 samples at 98.67 sec. Also shown is
the
> difference of the two magnitudes. A spectrum notch around 2800Hz is
> observed for some segments of samp2b.wav and another notch around 3500Hz
is
> observed for some other segments of samp2b.wav. Similar notches are
> observed in samp3b.wav. The attack fills in those notches of samp3b.wav
> with random but bounded coefficient values. We also submitted a variation
> of this attack involving different parameters for notch description. Both
> attacks were confirmed by SDMI oracle as successful.
>
>
>
> Fig. 6. Technology-B: FFT magnitudes of samp1b.wav and samp2b.wav and
their
> difference for 1000 samples at 98.67 sec.
>
> 3.3 Attacks on Challenge C
>
> By taking the difference of samp1c.wav and samp2c.wav, bursts of
narrowband
> signal are observed, as shown in Fig. 7. These narrow band bursts appear
to
> be centered around 1350 Hz. Two different attacks were applied to
Challenge
> C. In the first at- tack, we shifted the pitch of the audio by about a
> quartertone. In the second attack, we passed the signal through a bandstop
> filter centered around 1350Hz. Our submissions were confirmed by SDMI
> oracle as successful. In addition, the perceptual quality of both attacks
> has passed the "golden ear" testing conducted by SDMI after the 3-week
> challenge.
>
>
>
> Fig. 7. Challenge-C: Waveform of the difference between samp1c.wav and
> samp2c.wav.
>
> 3.4 Attack on Challenge F
>
> For Challenge F, we warped the time axis, by inserting a periodically
> varying delay. The delay function comes from our study on Technology-A,
and
> was in fact initially intended to undo the phase distortion applied by
> technology A. Therefore the perceptual quality of our attacked audio is
> expected to be better than or comparable to that of the audio watermarked
> by Technology-A. We also submitted variations of this at- tack involving
> different warping parameters and different delay function. They were
> confirmed by SDMI oracle as successful.
>
> 4 The Non-Watermark Technologies
>
> The HackSDMI challenge contained two "non-watermark" technologies.
> Together, they appear to be intended to prevent the creation of "mix" CDs,
> where a consumer might compile audio files from various locations to a
> writable CD. This would be enforced by universally embedding SMDI logic
> into consumer audio CD players.
>
> 4.1 Technology D
>
> According to SDMI, Technology D was designed to require "the presence of a
> CD in order to 'rip' or extract a song for SDMI purposes." The technology
> aimed to accomplish this by adding a 53.3 ms audio track (four blocks of
CD
> audio), which we will refer to as the authenticator, to each CD. The
> authenticator, combined with the CD's table of contents (TOC), would allow
> a SDMI device to recognize SDMI compliant CDs. For the challenge, SDMI
> provided 100 different "correct" TOC-authenticator pairs as well as 20
> "rogue tracks". A rogue track is a track length that does not match any of
> the track lengths in the 100 provided TOCs. The goal of the challenge was
> to submit to the SDMI oracle a correct authenticator for a TOC that
> contained at least one of the rogue tracks.
>
> The oracle for Technology D allowed several different query types. In the
> first type, an SDMI provided TOC-authenticator combination is submitted so
> a that user can "understand and verify the Oracle." According to SDMI, the
> result of this query should either be "admit" for a correct pair or
> "reject" for an incorrect pair. When we attempted this test a
SDMI-provided
> pair, the oracle responded that the submission was "invalid." After
> verifying that we had indeed submitted a correct pair, we attempted
several
> other submissions using different TOC-authenticator pairs as well as
> different browsers and operating systems3. We also submitted some pairs
> that the oracle should have rejected; these submissions were also declared
> "invalid." Though we alerted SDMI to this problem during the challenge,
the
> oracle was never repaired. For this reason, our analysis of Technology D
is
> incomplete and we lack definitive proof that it is correct. That having
> been said, we think that what we learned about this technology, even
> without the benefit of a correctly functioning oracle, is interesting.
>
> ____________________
>
> 3 Specifically, Netscape Navigator and Mozilla under Linux, Netscape
> Navigator under Windows NT, and Internet Explorer under Windows 98 and
> 2000.
>
>
> Analyzing the Signal Upon examination of the authenticator audio files, we
> discovered several patterns. First, the left and right channels contain
the
> same information. The two channels differ by a "noise vector" u, which is
a
> vector of small integer values that range from -8 and 8. Since the
> magnitude of the noise is so small, the noise vector does not
significantly
> affect the frequency characteristics of the signal. The noise values
appear
> to be random, but the noise vector is the same for each of the 100
provided
> authenticator files. In other other words, in any authenticator file, the
> difference between the left and right channels of the ith sample is a
> constant fixed value u[i]. This implies that the noise vector u does not
> encode any TOC-specific information.
>
> Second, the signal repeats with a period of 1024 samples. Because the full
> signal is 2352 samples long, the block repeats approximately 1.3 times.
> Similarly to the left and right channels of the signal, the first two
> iterations of the repeating signal differ by a constant noise vector v.
The
> difference between the ith sample of the first iteration and the ith
sample
> of the second iteration differ by a small (and apparently random) integer
> value v[i] ranging from -15 to 15. In addition, v is the same for each of
> the provided authenticator files, so v does not encode any TOC-specific
> information.
>
> Third, the first 100 samples and last 100 samples of the full signal are
> faded in and faded out, respectively. This is illustrated in Figure 8. The
> fade-in and fade-out are meaningless, however, because they simply destroy
> data that is repeated in the middle of the file. We conjecture that this
> fade-in and fade-out are included so that the audio signal does not sound
> offensive to a human ear.
>
>
>
> Fig. 8. In a Technology D Authenticator, the signal fades in, repeats, and
> fades out.
>
> Extracting the Data Frequency analysis on the 1024 sample block shows that
> almost all of the signal energy is concentrated in the 16-20kHz range, as
> shown in Figure 9. We believe this range was chosen because these
> frequencies are less audible to the human ear. Closer examination shows
> that this l6-20kHz range is divided up into 80 discrete bins, each of
which
> appears to carry one bit of information. As shown in Figure 10, these bits
> can be manually counted by a human using a graph of the magnitude of
signal
> in the frequency domain.
>
>
>
> Fig. 9. Magnitude vs. Frequency of Technology D Authenticator
>
>
>
>
> Fig. 10. Individual Bits >From a Technology D Authenticator
>
> Close inspection and pattern matching on these 80 bits of information
> reveals that there are only 16 bits of information repeated 5 times using
> different permutations. using the letters A-P to symbolize the 16 bits,
> these 5 permutations are described in Figure 11.
>
> ABCDEFGHIJKLMNOP
> OMILANHGPBDCKJFE
> PKINHODFMJBCAGLE
> FCKLGMEPNOADJBHI
> PMGHLECAKDONIFJB
>
> Fig. 11. The encoding of the 16 bits of data in Technology D
>
> Because of the malfunctioning oracle, we were unable to determine the
> function used to map TOCs to authenticators, but given an actual SDMI
> device, it would be trivial to brute force all 216 possibilities.
Likewise,
> without the oracle, we could not determine if there was any other signal
> present in the authenticator (e.g., in the phase of the frequency
> components with nonzero magnitude).
>
> For the moment, let us assume that the hash function used in Technology D
> has only 16 bits of output. Given the number of distinct CDs available, an
> attacker should be able to acquire almost, if not all, of the
> authenticators. We note that at 9 kilobytes each, a collection of 65,536
> files would fit nicely on a single CD. Many people have CD collections of
> 300+ discs, which by the birthday paradox makes it more likely than not
> that there is a hash collision among their own collection.
>
> Our results indicated that the hash function used in Technology D could be
> weak or may have less than 16 bits of output. In the 100 authenticator
> samples provided in the Technology D challenge, there were 2 pairs of
> 16-bit hash collisions. We will not step through the derivation here, but
> the probability of two or more collisions occurring in n samples of X
> equally likely possibilities is:
>
> If the 16-bit hash function output has 16 bits of entropy, the probability
> of 2 collisions occurring in n = 100 samples of X = 216 possibilities is
> 0.00254 (by the above 1.5 equation). If X ~ 211.5, the chances of two
> collisions occurring is about even. This suggests that either 4 bits of
the
> 16-bit hash output may be outputs of functions of the other 12 bits or the
> hash function used to generate the 16-bit signature is weak. It is also
> possible that the challenge designers purposefully selected TOCs that
yield
> collisions. The designers could gauge the progress of the contestants by
> observing whether anyone submits authenticator A with TOC B to the oracle,
> where authenticator A is equal to authenticator B. Besides the relatively
> large number of collisions in the provided authenticators, it appears that
> there are no strong biases in the authenticator bits such as significantly
> more or less 1's than 0's.
>
> 4.2 Technology E
>
> Technology E is designed to fix a specific bug in Technology D: the TOC
> only mentions the length of each song but says nothing about the contents
> of that song. As such, an attacker wishing to produce a mix CD would only
> need to find a TOC approximately the same as the desired mix CD, then copy
> the TOC and authenticator from that CD onto the mix CD. If the TOC does
not
> perfectly match the CD, the track skipping functionality will still work
> but will only get "close" to track boundaries rather than reaching them
> precisely. Likewise, if a TOC specified a track length longer than the
> track we wished to put there, we could pad the track with digital silence
> (or properly SDMI-watermarked silence, copied from another valid track).
> Regardless, a mix CD played from start to end would work perfectly.
> Technology E is designed to counter this attack, using the audio data
> itself as part of the authentication process.
>
> The Technology E challenge presented insufficient information to be
> properly studied. Rather than giving us the original audio tracks (from
> which we might study the unspecified watermarking scheme), we were instead
> given the tables of contents for 1000 CDs and a simple scripting language
> to specify a concatenation of music clips from any of these CDs. 'Me
oracle
> would process one of these scripts and then state whether the resulting CD
> would be rejected.
>
> While we could have mounted a detailed statistical analysis, submitting
> hundreds or thousands of queries to the oracle, we believe the challenge
> was fundamentally flawed. In practice, given a functioning SDMI device and
> actual SDMI-protected content, we could study the audio tracks in detail
> and determine the structure of the watermarking scheme.
>
> 5 Conclusion
>
> In this paper, we have presented an analysis of the technology challenges
> issued by the Secure Digital Music Initiative. Each technology challenge
> described a specific goal (e.g., remove a watermark from an audio track)
> and offered a Web-based oracle that would confirm whether the challenge
was
> successfully defeated.
>
> We have reverse-engineered and defeated all four of their audio
> watermarking technologies. We have studied and analyzed both of their
> "non-watermarking" technologies to the best of our abilities given the
lack
> of information available to us and given a broken oracle in one case.
>
> Some debate remains on whether our attacks damaged the audio beyond
> standards measured by "golden ear" human listeners. Given a sufficient
body
> of SDMI-protected content using the watermark schemes presented here, we
> are confident we could refine our attacks to introduce distortion no worse
> than the watermarks themselves introduce to the the audio. Likewise,
debate
> remains on whether we have truly defeated technologies D and E. Given a
> functioning implementation of these technologies, we are confident we can
> defeat them.
>
> Do we believe we can defeat any audio protection scheme? Certainly, the
> technical details of any scheme will become known publicly through reverse
> engineering. Using the techniques we have presented here, we believe no
> public watermark-based scheme intended to thwart copying will succeed.
> Other techniques may or may not be strong against attacks. For example,
the
> encryption used to protect consumer DVDs was easily defeated. Ultimately,
> if it is possible for a consumer to hear or see protected content, then it
> will be technically possible for the consumer to copy that content.
>
> References
>
> 1. R. J. ANDERSON, AND F. A. P. PETITCOLAS. On the limits of
steganography.
> IEEE Journal of Selected Areas in Communications 16,4 (May 1998),474-481.
>
> 2. R. P. BOGERT, M., AND J. W. TUKEY. The quefrency alanysis of time
series
> for echoes: Cepstrum, pseudo-autocovariance, cross-ceptsrum and
> saphe-cracking. In Proceedings of the Symposium on Time Series Analysis
> (Brown University, June 1962), pp. 209-243.
>
> 3. R. PETROVIC, J. M. WINOGRAD, K., AND E. METOIS. Apparatus and method
for
> encoding and decoding information in analog signals, Aug. 1999. US Patent
> No 05940135
http://www.delphion.com/details?pn=US05940135__.
>
> 4. SECURE DIGITAL MUSIC INITIATIVE. Call for Proposals for Phase II
> Screening Technology, Version 1.0, Feb. 2000.
>
http://www.sdmi.org/download/FRWG00022401-Ph2_CFPv1.0.PDF.
>
> 5. SECURE DIGITAL MUSIC INITIATIVE. SDMI public challenge, Sept. 2000.
>
http://www.hacksdmi.org.
>
> ------------------------------------------------------------------------
>
>
>
>
> --------------------++-----
> Les faits sont faits.
>
http://www.fis.utoronto.ca/~stalder
>
>
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