The Next-Generation Secure Computing Base (NGSCB; codenamed Palladium [1] and also known as Trusted Windows [2] ) is a software architecture designed by Microsoft which claimed to provide users of the Windows operating system with better privacy, security, and system integrity. [3] [4] NGSCB was the result of years of research and development within Microsoft to create a secure computing solution that equaled the security of closed platforms such as set-top boxes while simultaneously preserving the backward compatibility, flexibility, and openness of the Windows operating system. [5] [6] [7] Microsoft's primary stated objective with NGSCB was to "protect software from software." [5]
Part of the Trustworthy Computing initiative when unveiled in 2002, NGSCB was to be integrated with Windows Vista, then known as "Longhorn." [1] NGSCB relied on hardware designed by the Trusted Computing Group to produce a parallel operation environment hosted by a new hypervisor (referred to as a sort of kernel in documentation) called the "Nexus" that existed alongside Windows and provided new applications with features such as hardware-based process isolation, data encryption based on integrity measurements, authentication of a local or remote machine or software configuration, and encrypted paths for user authentication and graphics output. [3] [8] NGSCB would facilitate the creation and distribution of digital rights management (DRM) policies pertaining the use of information. [9]
NGSCB was subject to much controversy during its development, with critics contending that it would impose restrictions on users, enforce vendor lock-in, and undermine fair use rights and open-source software. It was first demonstrated by Microsoft at WinHEC 2003 [10] before undergoing a revision in 2004 that would enable earlier applications to benefit from its functionality. [11] Reports indicated in 2005 that Microsoft would change its plans with NGSCB so that it could ship Windows Vista by its self-imposed deadline year, 2006; instead, Microsoft would ship only part of the architecture, BitLocker, which can optionally use the Trusted Platform Module to validate the integrity of boot and system files prior to operating system startup. [12] Development of NGSCB spanned approximately a decade before its cancellation, [6] [13] the lengthiest development period of a major feature intended for Windows Vista.
NGSCB differed from technologies Microsoft billed as "pillars of Windows Vista"—Windows Presentation Foundation, Windows Communication Foundation, and WinFS—during its development in that it was not built with the .NET Framework and did not focus on managed code software development. [8] [14] NGSCB has yet to fully materialize; however, aspects of it are available in features such as BitLocker of Windows Vista, Measured Boot and UEFI of Windows 8, [15] Certificate Attestation of Windows 8.1, [16] Device Guard of Windows 10. [17] and Device Encryption in Windows 11 Home editions, with TPM 2.0 mandatory for installation.
Development of NGSCB began in 1997 after Peter Biddle conceived of new ways to protect content on personal computers. [1] [18] [19] [20] Biddle enlisted assistance from members from the Microsoft Research division and other core contributors eventually included Blair Dillaway, Brian LaMacchia, Bryan Willman, Butler Lampson, John DeTreville, John Manferdelli, Marcus Peinado, and Paul England. [21] Adam Barr, a former Microsoft employee who worked to secure the remote boot feature during development of Windows 2000 was approached by Biddle and colleagues during his tenure with an initiative tentatively known as "Trusted Windows," which aimed to protect DVD content from being copied. To this end, Lampson proposed the use of a hypervisor to execute a limited operating system dedicated to DVD playback alongside Windows 2000. [22] Patents for a DRM operating system were later filed in 1999 by England, DeTreville and Lampson; [23] [24] Lampson noted that these patents were for NGSCB. [25] Biddle and colleagues realized by 1999 that NGSCB was more applicable to privacy and security than content protection, and the project was formally given the green-light by Microsoft in October, 2001. [1] [19] [20] [26]
During WinHEC 1999, Biddle discussed intent to create a "trusted" architecture for Windows to leverage new hardware to promote confidence and security while preserving backward compatibility with previous software. [27] On October 11, 1999, the Trusted Computing Platform Alliance, a consortium of various technology companies including Compaq, Hewlett-Packard, IBM, Intel, and Microsoft was formed in an effort to promote personal computing confidence and security. [28] The TCPA released detailed specifications for a trusted computing platform with focus on features such as code validation and encryption based on integrity measurements, hardware-based key storage, and machine authentication; these features required a new hardware component designed by the TCPA called the "Trusted Platform Module" (referred to as a "Security Support Component", [9] "Security CoProcessor", [5] or "Security Support Processor" [5] in early NGSCB documentation).
At WinHEC 2000, Microsoft released a technical presentation on the topics of protection of privacy, security, and intellectual property titled "Privacy, Security, and Content in Windows Platforms", which focused on turning Windows into a "platform of trust" for computer security, user content, and user privacy. Notable in the presentation is the contention that "there is no difference between privacy protection, computer security, and content protection"—"assurances of trust must be universally true". [2] Microsoft reiterated these claims at WinHEC 2001. [29] NGSCB intended to protect all forms of content, unlike traditional rights management schemes which focus only on the protection of audio tracks or movies instead of users they have the potential to protect which made it, in Biddle's words, "egalitarian". [2] [30]
Microsoft held its first design review for the NGSCB in April 2002, with approximately 37 companies under a non-disclosure agreement. [19] NGSCB was publicly unveiled under its codename "Palladium" in a June 2002 article by Steven Levy for Newsweek that focused on its design, feature set, and origin. [31] [32] Levy briefly described potential features: access control, authentication, authorization, DRM, encryption, as well as protection from junk mail and malware, with example policies being email accessible only to an intended recipient and Microsoft Word documents readable for only a week after their creation; [1] Microsoft later release a guide clarifying these assertions as being hyperbolic; namely, that NGSCB would not intrinsically enforce content protection, or protect against junk mail or malware. Instead, it would provide a platform on which developers could build new solutions that did not exist by isolating applications and store secrets for them. [9] Microsoft was not sure whether to "expose the feature in the Control Panel or present it as a separate utility," but NGSCB would be an opt-in solution—disabled by default. [33]
Microsoft PressPass later interviewed John Manferdelli, who restated and expanded on many of the key points discussed in the article by Newsweek. Manferdelli described it as evolutionary platform for Windows in July, articulating how "'Palladium' will not require DRM, and DRM will not require 'Palladium'. [26] Microsoft sought a group program manager in August to assist in leading the development of several Microsoft technologies including NGSCB. [34] Paul Otellini announced Intel's support for NGSCB with a set of chipset, platform, and processor codenamed "LaGrande" at Intel Developer Forum 2002, [35] [36] which would provide an NGSCB hardware foundation and preserve backward compatibility with previous software. [37]
NGSCB was known as "Palladium" until January 24, 2003 when Microsoft announced it had been renamed as "Next-Generation Secure Computing Base." Project manager Mario Juarez stated this name was chosen to avoid legal action from an unnamed company which had acquired the rights to the "Palladium" name, as well as to reflect Microsoft's commitment to NGSCB in the upcoming decade. Juarez acknowledged the previous name was controversial, but denied it was changed by Microsoft to dodge criticism. [38]
The Trusted Computing Platform Alliance was superseded by the Trusted Computing Group in April 2003. [39] A principal goal of the new consortium was to produce a Trusted Platform Module (TPM) specification compatible with NGSCB; the previous specification, TPM 1.1 did not meet its requirements. [19] [40] TPM 1.2 was designed for compliance with NGSCB [41] and introduced many features for such platforms. [42] The first TPM 1.2 specification, Revision 62 was released in 2003. [43]
Biddle emphasized in June 2003 that hardware vendors and software developers were vital to NGSCB. [44] Microsoft publicly demonstrated NGSCB for the first time at WinHEC 2003, [10] [45] [46] where it protected data in memory from an attacker; prevented access to—and alerted the user of—an application that had been changed; and prevented a remote administration tool from capturing an instant messaging conversation. [47] [48] Despite Microsoft's desire to demonstrate NGSCB on hardware, [49] software emulation was required for as few hardware components were available. [48] Biddle reiterated that NGSCB was a set of evolutionary enhancements to Windows, basing this assessment on preserved backward compatibility and employed concepts in use before its development, but said the capabilities and scenarios it would enable would be revolutionary. [50] Microsoft also revealed its multi-year roadmap for NGSCB, [51] with the next major development milestone scheduled for the Professional Developers Conference, [48] [52] indicating that subsequent versions would ship concurrently with pre-release builds of Windows Vista; however, news reports suggested that NGSCB would not be integrated with Windows Vista when release, but it would instead be made available as separate software for the operating system. [53]
Microsoft also announced details related to adoption and deployment of NGSCB at WinHEC 2003, stating that it would create a new value proposition for customers without significantly increasing the cost of computers; NGSCB adoption during the year of its introductory release was not anticipated and immediate support for servers was not expected. [54] [55] On the last day of the conference, Biddle said NGSCB needed to provide users with a way to differentiate between secured and unsecured windows—that a secure window should be "noticeably different" to help protect users from spoofing attacks; [53] Nvidia was the earliest to announce this feature. [56] WinHEC 2003 represented an important development milestone for NGSCB. Microsoft dedicated several hours to presentations and released many technical whitepapers, [57] [58] [59] and companies including Atmel, [60] Comodo Group, [61] [62] Fujitsu, [61] and SafeNet [63] [64] produced preliminary hardware for the demonstration. Microsoft also demonstrated NGSCB at several U.S. campuses in California and in New York in June 2003. [52] [65]
NGSCB was among the topics discussed during Microsoft's PDC 2003 with a pre-beta software development kit, known as the Developer Preview, being distributed to attendees. [10] The Developer Preview was the first time that Microsoft made NGSCB code available to the developer community and was offered by the company as an educational opportunity for NGSCB software development. [66] With this release, Microsoft stated that it was primarily focused on supporting business and enterprise applications and scenarios with the first version of the NGSCB scheduled to ship with Windows Vista, adding that it intended to address consumers with a subsequent version of the technology, but did not provide an estimated time of delivery for this version. [8] [66] At the conference, Jim Allchin said that Microsoft was continuing to work with hardware vendors so that they would be able to support the technology, [67] and Bill Gates expected a new generation of central processing units (CPUs) to offer full support. [68] Following PDC 2003, NGSCB was demonstrated again on prototype hardware during the annual RSA Security conference in November. [69]
Microsoft announced at WinHEC 2004 that it would revise NSCB in response to feedback from customers and independent software vendors who did not desire to rewrite their existing programs in order to benefit from its functionality; [11] [70] the revision would also provide more direct support for Windows with protected environments for the operating system, its components, and applications, instead of it being an environment to itself and new applications. [71] The NGSCB secure input feature would also undergo a significant revision based on cost assessments, hardware requirements, and usability issues of the previous implementation. [72] There were subsequent reports that Microsoft would cease developing NGSCB; [73] [74] Microsoft denied these reports and reaffirmed its commitment to delivery. [14] [75] Additional reports published later that year suggested that Microsoft would make even additional changes based on feedback from the industry. [6] [76]
Microsoft's absence of continual updates on NGSCB progress in 2005 had caused industry insiders to speculate that NGSCB had been cancelled. [77] At the Microsoft Management Summit event, Steve Ballmer said that the company would build on the security foundation it had started with the NGSCB to create a new set of virtualization technologies for Windows, [78] which were later Hyper-V. Reports during WinHEC 2005 indicated Microsoft scaled back its plans for NGSCB, so that it could to ship Windows Vista—which had already been beset by numerous delays and even a "development reset"—within a reasonable timeframe; instead of isolating components, NGSCB would offer "Secure Startup" ("BitLocker Drive Encryption") to encrypt disk volumes and validate both pre-boot firmware and operating system components. [12] [79] [80] [81] Microsoft intended to deliver other aspects of NGSCB later. [3] Jim Allchin stated NGSCB would "marry hardware and software to gain better security", which was instrumental in the development of BitLocker. [81]
A complete Microsoft-based Trusted Computing-enabled system will consist not only of software components developed by Microsoft but also of hardware components developed by the Trusted Computing Group. The majority of features introduced by NGSCB are heavily reliant on specialized hardware and so will not operate on PCs predating 2004.
In current Trusted Computing specifications, there are two hardware components: the Trusted Platform Module (TPM), which will provide secure storage of cryptographic keys and a secure cryptographic co-processor, and a curtained memory feature in the CPU. In NGSCB, there are two software components, the Nexus, a security kernel that is part of the Operating System that provides a secure environment (Nexus mode) for trusted code to run in, and Nexus Computing Agents (NCAs), trusted modules which run in Nexus mode within NGSCB-enabled applications.
At the time of manufacture, a cryptographic key is generated and stored within the TPM. This key is never transmitted to any other component, and the TPM is designed in such a way that it is extremely difficult to retrieve the stored key by reverse engineering or any other method, even to the owner. Applications can pass data encrypted with this key to be decrypted by the TPM, but the TPM will only do so under certain strict conditions. Specifically, decrypted data will only ever be passed to authenticated, trusted applications, and will only ever be stored in curtained memory, making it inaccessible to other applications and the Operating System. Although the TPM can only store a single cryptographic key securely, secure storage of arbitrary data is by extension possible by encrypting the data such that it may only be decrypted using the securely stored key.
The TPM is also able to produce a cryptographic signature based on its hidden key. This signature may be verified by the user or by any third party, and so can therefore be used to provide remote attestation that the computer is in a secure state.
NGSCB also relies on a curtained memory feature provided by the CPU. Data within curtained memory can only be accessed by the application to which it belongs, and not by any other application or the Operating System. The attestation features of the TPM can be used to confirm to a trusted application that it is genuinely running in curtained memory; it is therefore very difficult for anyone, including the owner, to trick a trusted application into running outside of curtained memory. This in turn makes reverse engineering of a trusted application extremely difficult.
NGSCB-enabled applications are to be split into two distinct parts, the NCA, a trusted module with access to a limited Application Programming Interface (API), and an untrusted portion, which has access to the full Windows API. Any code which deals with NGSCB functions must be located within the NCA.
The reason for this split is that the Windows API has developed over many years and is as a result extremely complex and difficult to audit for security bugs. To maximize security, trusted code is required to use a smaller, carefully audited API. Where security is not paramount, the full API is available.
NGSCB enables new categories of applications and scenarios. Examples of uses cited by Microsoft include decentralized access control policies; digital rights management services for consumers, content providers, and enterprises; protected instant messaging conversations and online transactions; and more secure forms of machine health compliance, network authentication, and remote access. [5] NGSCB-secured virtual private network access was one of the earliest scenarios envisaged by Microsoft. [82] NGSCB can also strengthen software update mechanisms such as those belonging to antivirus software or Windows Update. [83]
An early NGSCB privacy scenario conceived of by Microsoft is the "wine purchase scenario," where a user can safely conduct a transaction with an online merchant without divulging personally identifiable information during the transaction. [84] With the release of the NGSCB Developer Preview during PDC 2003, Microsoft emphasized the following enterprise applications and scenarios: document signing, secured data viewing, secured instant messaging, and secured plug-ins for emailing. [8]
"The concept of machine identity actually gives you the ability to do things like strengthen antivirus updates because you can start creating circumstances where you sort of create a little secure partition, or secure space within the PC, and that can let you do things like work around rootkits. [...] A lot of what is happening in the arms race of security today is an attempt to subvert an operating system so that the operating system is no longer behaving in the manner in which it was either designed or the user wants—without the user knowing—right? And in other cases, it's about creating a fake user which then does things on your behalf—which are not really on your behalf: spends your money, gives away your data, gives away personally identifiable information. So anything that lets you create a stronger, more immutable identity combination like: "this is the machine, this is the software, this is the operating system, this is the service, this is the user" is something that can benefit users because things that work on chiseling into those spaces are less effective."
— Peter Biddle. [83]
During WinHEC 2004, Microsoft revealed two features based on its revision of NGSCB, Cornerstone and Code Integrity Rooting: [71]
BitLocker is the combination of these features; "Cornerstone" was the codename of BitLocker, [85] [86] and BitLocker validates pre-boot firmware and operating system components before boot, which protects SYSKEY from unauthorized access; an unsuccessful validation prohibits access to a protected system. [87] [88]
Reaction to NGSCB after its unveiling by Newsweek was largely negative. While its security features were praised, [89] [90] critics contended that NGSCB could be used to impose restrictions on users; [90] [91] [92] [93] [94] lock-out competing software vendors; [91] [95] [94] [96] and undermine fair use rights and open source software such as Linux. [94] [97] [98] Microsoft's characterization of NGSCB as a security technology was subject to criticism as its origin focused on DRM. [68] [99] NGSCB's announcement occurred only a few years after Microsoft was accused of anticompetitive practices during the United States v. Microsoft Corporation antitrust case, a detail which called the company's intentions for the technology into question—NGSCB was regarded as an effort by the company to maintain its dominance in the personal computing industry. [100] The notion of a "Trusted Windows" architecture—one that implied Windows itself was untrustworthy—would also be a source of contention within the company itself. [101]
After NGSCB's unveiling, Microsoft drew frequent comparisons to Big Brother, an oppressive dictator of a totalitarian state in George Orwell's dystopian novel Nineteen Eighty-Four . The Electronic Privacy Information Center legislative counsel, Chris Hoofnagle, described Microsoft's characterization of the NGSCB as "Orwellian." [102] Big Brother Awards bestowed Microsoft with an award because of NGSCB. [84] Bill Gates addressed these comments at a homeland security conference by stating that NGSCB "can make our country more secure and prevent the nightmare vision of George Orwell at the same time." [103] Steven Levy—the author who unveiled the existence of the NGSCB—claimed in a 2004 front-page article for Newsweek that NGSCB could eventually lead to an "information infrastructure that encourages censorship, surveillance, and suppression of the creative impulse where anonymity is outlawed and every penny spent is accounted for." [104] However, Microsoft outlined a scenario enabled by NGSCB that allows a user to conduct a transaction without divulging personally identifiable information. [84]
Ross Anderson of Cambridge University was among the most vocal critics of NGSCB and of Trusted Computing. Anderson alleged that the technologies were designed to satisfy federal agency requirements; enable content providers and other third-parties to remotely monitor or delete data in users' machines; use certificate revocation lists to ensure that only content deemed "legitimate" could be copied; and use unique identifiers to revoke or validate files; he compared this to the attempts by the Soviet Union to "register and control all typewriters and fax machines." [94] [105] Anderson also claimed that the TPM could control the execution of applications on a user's machine and, because of this, bestowed to it a derisive "Fritz Chip" name in reference to United States Senator Ernest "Fritz" Hollings, who had recently proposed DRM legislation such as the Consumer Broadband and Digital Television Promotion Act for consumer electronic devices. Anderson's report was referenced extensively in the news media and appeared in publications such as BBC News, [106] The New York Times , [107] and The Register . [108] David Safford of IBM Research stated that Anderson presented several technical errors within his report, namely that the proposed capabilities did not exist within any specification and that many were beyond the scope of trusted platform design. [109] Anderson later alleged that BitLocker was designed to facilitate DRM and to lock out competing software on an encrypted system, [110] and, in spite of his allegation that NGSCB was designed for federal agencies, advocated for Microsoft to add a backdoor to BitLocker. [111] Similar sentiments were expressed by Richard Stallman, founder of the GNU Project and Free Software Foundation, [112] who alleged that Trusted Computing technologies were designed to enforce DRM and to prevent users from running unlicensed software. In 2015, Stallman stated that "the TPM has proved a total failure" for DRM and that "there are reasons to think that it will not be feasible to use them for DRM." [112]
"We are not going to use Palladium to make our customers—our favorite people—angry at us."
Peter Biddle [113]
After the release of Anderson's report, Microsoft stated in an NGSCB FAQ that "enhancements to Windows under the NGSCB architecture have no mechanism for filtering content, nor do they provide a mechanism for proactively searching the Internet for 'illegal' content [...] Microsoft is firmly opposed to putting 'policing functions' into nexus-aware PCs and does not intend to do so" and that the idea was in direct opposition with the design goals set forth for NGSCB, which was "built on the premise that no policy will be imposed that is not approved by the user." [9] Concerns about the NGSCB TPM were also raised in that it would use what are essentially unique machine identifiers, [5] which drew comparisons to the Intel Pentium III processor serial number, a unique hardware identification number of the 1990s viewed as a risk to end-user privacy. [94] [114] [115] NGSCB, however, mandates that disclosure or use of the keys provided by the TPM be based solely on user discretion; [9] [41] in contrast, Intel's Pentium III included a unique serial number that could potentially be revealed to any application. [116] NGSCB, also unlike Intel's Pentium III, would provide optional features to allow users to indirectly identify themselves to external requestors. [9]
In response to concerns that NGSCB would take control away from users for the sake of content providers, Bill Gates stated that the latter should "provide their content in easily accessible forms or else it ends up encouraging piracy." [117] Bryan Willman, Marcus Peinado, Paul England, and Peter Biddle—four NGSCB engineers—realized early during the development of NGSCB that DRM would ultimately fail in its efforts to prevent piracy. [101] In 2002, the group released a paper titled "The Darknet and the Future of Content Distribution" that outlined how content protection mechanisms are demonstrably futile. [118] The paper's premise circulated within Microsoft during the late 1990s and was a source of controversy within Microsoft; Biddle stated that the company almost terminated his employment as a result of the paper's release. [101] A 2003 report published by Harvard University researchers suggested that NGSCB and similar technologies could facilitate the secure distribution of copyrighted content across peer-to-peer networks. [119] [120]
Not all assessments were negative. Paul Thurrott praised NGSCB, stating that it was "Microsoft's Trustworthy Computing initiative made real" and that it would "form the basis of next-generation computer systems." [121] Scott Bekker of Redmond Magazine stated that NGSCB was misunderstood because of its controversy and that it appeared to be a "promising, user-controlled defense against privacy intrusions and security violations." [89] In February 2004, In-Stat/MDR, publisher of the Microprocessor Report, bestowed NGSCB with its Best Technology award. [122] Malcom Crompton, Australian Privacy Commissioner, stated that "NGSCB has great privacy enhancing potential [...] Microsoft has recognised there is a privacy issue [...] we should all work with them, give them the benefit of the doubt and urge them to do the right thing." [123] When Microsoft announced at WinHEC 2004 that it would be revising NGSCB so that previous applications would not have to be rewritten, Martin Reynolds of Gartner praised the company for this decision as it would create a "more sophisticated" version of NGSCB that would simplify development. [124] David Wilson, writing for South China Morning Post, defended NGSCB by saying that "attacking the latest Microsoft monster is an international blood sport" and that "even if Microsoft had a new technology capable of ending Third World hunger and First World obesity, digital seers would still lambaste it because they view Bill Gates as a grey incarnation of Satan." [125] Microsoft noted that negative reaction to NGSCB gradually waned after events such as the USENIX Annual Technical Conference in 2003, [71] and several Fortune 500 companies also expressed interest in it. [71] [126]
When reports announced in 2005 that Microsoft would scale back its plans and incorporate only BitLocker with Windows Vista, concerns pertaining digital rights management, erosion of user rights, and vendor lock-in remained. [12] [80] [127] [128] In 2008, Biddle stated that negative perception was the most significant contributing factor responsible for the cessation of NGSCB's development. [129]
In an article in 2003, D. Boneh and D. Brumley indicated that projects like NGSCB may be vulnerable to timing attacks. [130]
Trusted Computing (TC) is a technology developed and promoted by the Trusted Computing Group. The term is taken from the field of trusted systems and has a specialized meaning that is distinct from the field of confidential computing. With Trusted Computing, the computer will consistently behave in expected ways, and those behaviors will be enforced by computer hardware and software. Enforcing this behavior is achieved by loading the hardware with a unique encryption key that is inaccessible to the rest of the system and the owner.
A secure cryptoprocessor is a dedicated computer-on-a-chip or microprocessor for carrying out cryptographic operations, embedded in a packaging with multiple physical security measures, which give it a degree of tamper resistance. Unlike cryptographic processors that output decrypted data onto a bus in a secure environment, a secure cryptoprocessor does not output decrypted data or decrypted program instructions in an environment where security cannot always be maintained.
The Windows Hardware Engineering Community (WinHEC) is a series of technical conferences and workshops, where Microsoft elaborates on its hardware plans for Windows devices.
The Smart Personal Objects Technology (SPOT) is a discontinued initiative by Microsoft to create intelligent and personal home appliances, consumer electronics, and other objects through new hardware capabilities and software features.
Windows Vista is a major release of the Windows NT operating system developed by Microsoft. It was the direct successor to Windows XP, released five years earlier, which was then the longest time span between successive releases of Microsoft Windows. It was released to manufacturing on November 8, 2006, and over the following two months, it was released in stages to business customers, original equipment manufacturers (OEMs), and retail channels. On January 30, 2007, it was released internationally and was made available for purchase and download from the Windows Marketplace; it is the first release of Windows to be made available through a digital distribution platform.
The Trusted Computing Group is a group formed in 2003 as the successor to the Trusted Computing Platform Alliance which was previously formed in 1999 to implement Trusted Computing concepts across personal computers. Members include Intel, AMD, IBM, Microsoft, and Cisco.
Trusted Platform Module (TPM) is an international standard for a secure cryptoprocessor, a dedicated microcontroller designed to secure hardware through integrated cryptographic keys. The term can also refer to a chip conforming to the standard ISO/IEC 11889. Common uses are to verify platform integrity, and to store disk encryption keys.
Peter Nicholas Biddle is a technology evangelist from the United States. His primary fields of interest while employed at major technology companies such as Intel and Microsoft were content distribution, secure computing, and encryption. Since his departure from Intel, he has co-founded and led several industrial design companies.
BitLocker is a full volume encryption feature included with Microsoft Windows versions starting with Windows Vista. It is designed to protect data by providing encryption for entire volumes. By default, it uses the Advanced Encryption Standard (AES) algorithm in cipher block chaining (CBC) or "xor–encrypt–xor (XEX)-based Tweaked codebook mode with ciphertext Stealing" (XTS) mode with a 128-bit or 256-bit key. CBC is not used over the whole disk; it is applied to each individual sector.
Defective by Design (DBD) is a grassroots anti-digital rights management (DRM) initiative by the Free Software Foundation (FSF) and CivicActions. Launched in 2006, DBD believes that DRM makes technology deliberately defective, negatively affects digital freedoms, and is "a threat to innovation in media, the privacy of readers, and freedom for computer users." The initiative regularly campaigns against the use of DRM by the media industry and software industry to increase awareness of the anti-DRM movement and pressure industries into no longer using DRM. They are known for their use of hazmat suits in their demonstrations.
There are a number of security and safety features new to Windows Vista, most of which are not available in any prior Microsoft Windows operating system release.
Windows Error Reporting (WER) is a crash reporting technology introduced by Microsoft with Windows XP and included in later Windows versions and Windows Mobile 5.0 and 6.0. Not to be confused with the Dr. Watson debugging tool which left the memory dump on the user's local machine, Windows Error Reporting collects and offers to send post-error debug information using the Internet to Microsoft when an application crashes or stops responding on a user's desktop. No data is sent without the user's consent. When a crash dump reaches the Microsoft server, it is analyzed, and information about a solution is sent back to the user if available. Solutions are served using Windows Error Reporting Responses. Windows Error Reporting runs as a Windows service. Kinshuman Kinshumann is the original architect of WER. WER was also included in the Association for Computing Machinery (ACM) hall of fame for its impact on the computing industry.
The various versions of Microsoft's desktop operating system, Windows, have received various criticisms since Microsoft's inception.
Free Software Foundation anti-Windows campaigns are the events targeted against a line of Microsoft Windows operating systems. They are paralleling the Defective by Design campaign against digital rights management technologies, but they instead target Microsoft's operating systems instead of DRM itself.
Windows Speech Recognition (WSR) is speech recognition developed by Microsoft for Windows Vista that enables voice commands to control the desktop user interface, dictate text in electronic documents and email, navigate websites, perform keyboard shortcuts, and operate the mouse cursor. It supports custom macros to perform additional or supplementary tasks.
In computer security, a cold boot attack is a type of side channel attack in which an attacker with physical access to a computer performs a memory dump of a computer's random-access memory (RAM) by performing a hard reset of the target machine. Typically, cold boot attacks are used for retrieving encryption keys from a running operating system for malicious or criminal investigative reasons. The attack relies on the data remanence property of DRAM and SRAM to retrieve memory contents that remain readable in the seconds to minutes following a power switch-off.
Pre-boot authentication (PBA) or power-on authentication (POA) serves as an extension of the BIOS, UEFI or boot firmware and guarantees a secure, tamper-proof environment external to the operating system as a trusted authentication layer. The PBA prevents anything being read from the hard disk such as the operating system until the user has confirmed they have the correct password or other credentials including multi-factor authentication.
Windows 10 is a major release of Microsoft's Windows NT operating system. The successor to Windows 8.1, it was released to manufacturing on July 15, 2015, and later to retail on July 29, 2015. Windows 10 was made available for download via MSDN and TechNet, as a free upgrade for retail copies of Windows 8 and Windows 8.1 users via the Microsoft Store, and to Windows 7 users via Windows Update. Unlike previous Windows NT releases, Windows 10 receives new builds on an ongoing basis, which are available at no additional cost to users; devices in enterprise environments can alternatively use long-term support milestones that only receive critical updates, such as security patches.
VeraCrypt is a free and open-source utility for on-the-fly encryption (OTFE). The software can create a virtual encrypted disk that works just like a regular disk but within a file. It can also encrypt a partition or the entire storage device with pre-boot authentication.
Windows 10, a proprietary operating system released by Microsoft in July 2015, has been criticized by reviewers and users. Due to issues mostly about privacy, it has been the subject of a number of negative assessments by various groups.
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: CS1 maint: unfit URL (link)I think what you have to watch out for here is that from later this year the encryption landscape is going to change with the release of Microsoft [Windows] Vista, the next generation of [the] Windows operating system, which will support the use of a chip called a TPM which manufacturers are putting on PC motherboards. [...] This is being done for a number of commercial reasons: firstly, to do digital rights management on downloaded music and films and, secondly, by the software vendors so they can lock the customers in tightly and charge more for their products. [...]
EDITED TO ADD (5/3): BitLocker is not a DRM system. However, it is straightforward to turn it into a DRM system. Simply give programs the ability to require that files be stored only on BitLocker-enabled drives, and then only be transferrable to other BitLocker-enabled drives. How easy this would be to implement, and how hard it would be to subvert, depends on the details of the system.