After many years of research and testing, in mid-August 2023, the U.S. National Institute of Standards and Technology (NIST) finally introduced fully-fledged post-quantum encryption standards — FIPS 203, FIPS 204, and FIPS 205. So let’s discuss them and see why they should be adopted as soon as possible.

Why do we need post-quantum cryptography?

First, let’s briefly outline the threat quantum computers pose to cryptography. The issue lies in the fact that quantum computing can be used to break asymmetric encryption. Why is this important? As a rule, today’s communication encryption typically uses a dual system:

All messages are encrypted using a symmetric algorithm (like AES), which involves a single key shared by all participants. Symmetric algorithms work well and fast, but there’s a problem: the key must be somehow securely transmitted between interlocutors without being intercepted.
That’s why asymmetric encryption is used to transmit this key (like RSA or ECDH). Here, each participant has a pair of keys — a private and a public one — which are mathematically related. Messages are encrypted with the public key, and decrypted only with the private one. Asymmetric encryption is slower, so it’s impractical to use it for all messages.

The privacy of correspondence is ensured by the fact that calculating a private key from the corresponding public key is an extremely resource-intensive task — potentially taking decades, centuries, or even millions of years to solve. That is — if we’re using traditional computers.

Quantum computers significantly speed up such calculations. Specifically, Shor’s quantum algorithm can crack private keys for asymmetrical encryption much faster than its creators expected — in minutes or hours rather than years and centuries.

Once the private key for asymmetric encryption has been calculated, the symmetric key used to encrypt the main correspondence can also be obtained. Thus, the entire conversation can be read.

In addition to communication protocols, this also puts digital signatures at risk. In the majority of cases, digital signatures rely on the same asymmetric encryption algorithms (RSA, ECDSA) that are vulnerable to attacks by quantum computers.

Today’s symmetric encryption algorithms, on the other hand, are much less at risk from quantum computers than asymmetric ones. For example, in the case of AES, finding a 256-bit key using Grover’s quantum algorithm is like finding a 128-bit key on a regular computer. The same applies to hashing algorithms.

The trio of post-quantum cryptography standards: FIPS 203, FIPS 204, and FIPS 205

The primary task for cryptographers has become the development of quantum-resistant asymmetric encryption algorithms, which could be used in key transfer and digital signature mechanisms. The result of this effort: the post-quantum encryption standards FIPS 203, FIPS 204, and FIPS 205, introduced by the U.S. National Institute of Standards and Technology (NIST).

FIPS 203

FIPS 203 describes a key encapsulation mechanism based on lattice theory — ML-KEM (Module-Lattice-Based Key-Encapsulation Mechanism). This asymmetric cryptographic system — which is resistant to quantum algorithm attacks — is designed to transfer encryption keys between interlocutors.

ML-KEM was developed as part of CRYSTALS (Cryptographic Suite for Algebraic Lattices) and is also known as CRYSTALS-Kyber, or simply Kyber.

FIPS 203 features three parameter variants for ML-KEM:

ML-KEM-512: Security level 1 (equivalent to AES-128);
ML-KEM-768: Security level 3 (equivalent to AES-192);
ML-KEM-1024: Security level 5 (equivalent to AES-256).

FIPS 204

FIPS 204 defines a digital signature mechanism, also based on algebraic lattices, called ML-DSA (Module-Lattice-Based Digital Signature Algorithm). Previously known as CRYSTALS-Dilithium, this mechanism was developed within the same CRYSTALS project as Kyber.

FIPS 204 has three parameter variants for ML-DSA:

ML-DSA-44: Security level 2 (equivalent to SHA3-256);
ML-DSA-65: Security level 3;
ML-DSA-87: Security level 5.

FIPS 205

The third standard, FIPS 205, describes an alternative digital signature mechanism: SLH-DSA (Stateless Hash-Based Digital Signature Algorithm). Unlike the other two cryptosystems, which are based on algebraic lattices, SLH-DSA is based on hashing. This mechanism is also known as SPHINCS+.

This standard involves the use of both the SHA2 hash function with a fixed output length, as well as the SHAKE function with an arbitrary length. For each base cryptographic-strength level, SLH-DSA offers sets of parameters optimized for a higher speed (f — fast), or a smaller signature size (s — small). Thus, FIPS 205 has more variety — with as many as 12 parameter options:

SLH-DSA-SHA2-128s, SLH-DSA-SHAKE-128s, SLH-DSA-SHA2-128f, SLH-DSA-SHAKE-128f: Security level 1;
SLH-DSA-SHA2-192s, SLH-DSA-SHAKE-192s, SLH-DSA-SHA2-192f, SLH-DSA-SHAKE-192f: Security level 3;
SLH-DSA-SHA2-256s, SLH-DSA-SHAKE-256s, SLH-DSA-SHA2-256f, SLH-DSA-SHAKE-256f: Security level 5.

HNDL, and why it’s time to start using post-quantum encryption

For now, the threat of quantum algorithms breaking asymmetric encryption is mostly theoretical. Existing quantum computers lack the power to actually do it in practice.

Until last year, it was believed that sufficiently powerful quantum systems were still a decade away. However, a 2023 paper suggested ways to optimize hacking using a combination of classic and quantum computing. As a result, the timeline for achieving quantum supremacy seems to have shifted: RSA-2048 could very well be broken within a few years.

It’s also important to remember the concept of HNDL — “harvest now, decrypt later” (or SNDL — “store now, decrypt later”). Attackers with significant resources could already be collecting and storing data that can’t currently be decrypted. Once quantum computers with sufficient power become available, they’ll immediately begin retroactive decryption. Of course, when this fateful moment comes, it will already be too late, so quantum-resistant encryption standards should be implemented right now.

The ideal approach to deploying post-quantum cryptography based on established IT industry practices is hybrid encryption; that is, encrypting data in two layers: first with a classical algorithm, then with a post-quantum one. This forces attackers to contend with both cryptosystems — significantly lowering the chances of a successful breach. This approach is already being used by Signal, Apple, Google, and Zoom.

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At the time of writing, Pavel Durov has been charged in France, but hasn’t appeared in court yet. How things will pan out in court remains very unclear, but in the meantime scammers are already exploiting the massive attention and panic surrounding Telegram, while much dubious advice on social media is circulating regarding what to do now with the app. Our two-cents in a nutshell: Telegram users should remain calm, and act depending only on the facts as they currently stand. Now for what we can recommend today in detail…

Chat privacy and the “keys to Telegram”

Put simply, most chats on Telegram cannot be considered confidential — and this has always been the case. If you’ve been exchanging sensitive information on Telegram without using secret chats, consider it compromised. Move your private communications to another messenger following these recommendations.

Many news outlets suggest that the main complaint against Durov and Telegram is their refusal to cooperate with the French authorities and provide the “keys to Telegram”. Supposedly, Durov possesses some kind of cryptographic keys, which can be used to read users’ messages. In fact, few people really know how the Telegram server is structured, but from the available information, it is known that the bulk of correspondence is stored on servers in minimally encrypted form — that is, the decryption keys are stored within the same Telegram infrastructure. The creators claim that chats are stored in one country, while keys are stored in another, but considering that all the servers communicate with each other, it’s not clear how effective this security measure is in practice. It would help if the servers were confiscated in one country, but that’s about it. End-to-end encryption, which is standard in other messengers (WhatsApp, Signal and even Viber), is called “secret chat” in Telegram. It’s somewhat hidden in the depths of the interface and needs to be manually activated for selected personal chats. All group chats, channels, and standard personal correspondence lack end-to-end encryption and can be read at least on Telegram servers. Moreover, for both secret chats and everything else, Telegram uses its own non-standard protocol — MTProto — which has been found to contain serious cryptographic vulnerabilities. Therefore, Telegram correspondence can theoretically be read by:

Telegram server administrators
Hackers who’ve successfully breached Telegram servers and installed spyware
Third parties with some kind of access granted by Telegram administrators
A third party that has discovered cryptographic vulnerabilities in Telegram protocols and can read (selectively or in full) at least non-secret chats by intercepting the traffic of some users

Deleting correspondence

Some categories of users have been advised to delete old chats in Telegram, such as work-related ones. This advice seems questionable, because in databases (where correspondence is stored on the server), entries are rarely actually deleted; they’re simply marked as such. Moreover, like any major IT infrastructure, Telegram likely implements a robust data backup system, meaning “deleted” messages will be kept at least in database backups. It may be more effective for both chat participants (or group admins) to completely delete the chat. However, the issue of backups would still remain.

Backing up chats

A number of observers have expressed concerns that Telegram could be removed from app stores, blocked, or otherwise disrupted. While this seems unlikely, backing up important correspondence, photos and documents is still good practice in digital hygiene.

To save a backup of important personal correspondence, you need to install Telegram on your computer (official client here), log into your account, and then navigate to Settings → Advanced → Export Telegram data.

In the pop-up window, you can select the data you want to export (personal chats, group chats — with or without photos and videos), set download size limits, and choose the data format — HTML, which can be viewed in any browser, or JSON for automated processing by third-party apps.

Downloading the data to your computer could take several hours and may require dozens or even hundreds of gigabytes of free space, depending on how much you use Telegram and the export settings. You can close the export window, but be sure not to exit the app itself or disconnect your computer from the internet or the mains. We recommend only using the backup feature in the official client.

“Preventing Telegram’s deletion” from smartphones

First, let’s look at iOS. The folks at Cupertino don’t remove apps from users’ smartphones — even if apps are removed from the App Store, so any advice about stopping Telegram being deleted from iPhones is bogus. Moreover, a popular method for “Telegram deletion prevention” circulating online — that using the Screen Time menu — doesn’t prevent Apple from deleting apps; it only prevents certain users (e.g., children) from deleting apps themselves: as such it’s a parental control feature. And there’s more: Durov’s arrest has revived the old false claim about Telegram being removed remotely from iPhones, which both Apple and Telegram officially denied back in 2021.

As for Android, Google also doesn’t typically delete apps — except when it’s 100% malicious software. True, such guarantees don’t apply to all holders of other ecosystems (Samsung, Xiaomi and so on), but on Android it’s easy to install Telegram directly from the Telegram website.

Alternative clients

There are unofficial but still functional and legal clients for Telegram, and even an “official alternative client” — Telegram X. These clients all use the Telegram API, but it’s unclear whether they provide any additional benefits or increased security. The top five alternative clients on Google Play each talk about “improved security” – but only refer to features like hiding chats on a device.

Of course, you may end up downloading malware disguised as an alternative Telegram client — scammers don’t miss an opportunity to exploit the app’s popularity. If you’re considering alternative clients, follow these safety guidelines:

Download them only from official app stores.
Make sure the app has been around for a while, and has high ratings and a large number of downloads.
Use reliable antivirus protection across all platforms such as Kaspersky Premium.

Fundraising for Durov and defending free speech

This isn’t directly related to Telegram chats, but it’s important to beware also of scammers posing as those raising funds for Pavel Durov’s legal defense (like, he really needs the cash), while actually aiming to steal payment information or cryptocurrency donations. Treat such requests with extreme suspicion, and verify whether the alleged organization really exists and really is conducting such a campaign. For more on charity scams, check out our dedicated article.

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The aggressive introduction of AI in Microsoft products, geopolitical tensions, and a series of cybersecurity incidents involving the Redmond giant are pushing many organizations worldwide to switch to open-source alternatives to Windows and Office. To replace the latter, both OpenOffice and its offshoot LibreOffice are very popular. They’re available on all major platforms — including Linux, offer functionality comparable to MS Office, and come with the licenses suitable for large companies.

Due to their similarity to MS Office, the risks associated with using these suites are also similar: software vulnerabilities or unsecure settings can result in the execution of malicious code on the computer, or stealthily redirect the user to phishing links. And these threats aren’t mere theory — malicious documents in .odt files and other “open” document formats have been encountered in the wild. To mitigate these risks, the German Federal Office for Information Security (BSI) has issued public recommendations for secure LibreOffice settings. Let’s look together at the most important ones when using LibreOffice in organizations.

Configuration tips

The tips below apply to safe setup of LibreOffice on Linux, MacOS, or Windows in a managed corporate environment (through group policies and other centralized control tools). The tips concern the Writer, Calc, Impress, Base, Math, and Draw components of version 7.2.x. The recommended settings are based on the following considerations:

The end user should make the fewest possible decisions affecting security.
The functionality of the application should not be significantly reduced.
Unnecessary features should be deactivated to reduce the attack surface.
Whenever possible, transfer of data from the product to the manufacturer should be disabled.
External cloud services should be avoided unless they’re necessary for the organization’s business processes.

Configuration storage

LibreOffice settings can be modified by the administrator or by the user. Initial administrative settings are stored in the LibreOffice folder. On all platforms, the settings are applied as XML files (settings.xml), but they can also be stored in platform-specific formats (registry in Windows, dconf in Linux). For medium and large organizations, XML is recommended.

If a setting shouldn’t be modified by users, it can be marked as finalized in the administrator settings.
For example, below is a settings snippet that disables saving the document-author information (the RemovePersonalInfoOnSaving setting in the group org.openoffice.Office.Common/Security/Scripting) and prohibits changing this setting:

<item oor:path=”/org.openoffice.Office.Common/Security/Scripting”>
<prop about:name=”RemovePersonalInfoOnSaving” about:finalized=”false” about:op=”fuse” oor:type=”xs:boolean”>
<value>true</value>
</prop>
</item>

Folders for administrative settings (in version 7.2) are listed below:

Linux: /opt/libreoffice7.2/share/registry/res
MacOS: /Applications/LibreOffice.app/Contents/Resources/registry/res
Windows: C:Program FilesLibreOfficeshareregistryres

Settings to change

Many of LibreOffice’s settings are secure by default. Here, we’ll focus on those that need to be tightened.

Macro execution

By default, any signed macros are executed, so this setting must be tightened to the max — allowing only macros from trusted folders to be executed. So in the group org.openoffice.Office.Common/Security/Scripting, set the MacroSecurityLevel to 3:

<prop over:name=”MacroSecurityLevel” over:finalized=”true” over:op=”fuse” over:type=”xs:int”>
<value>3</value>
</prop>

To disable macros entirely, set the DisableMacrosExecution option from the same group to true with the finalized tag.

Trusted folders

By default, LibreOffice updates the list of trusted folders based on user activity — often including folders like Downloads. To clearly set trusted document storage locations, list them in the SecureURL option. The list can be left empty.

<item oor:path=”/org.openoffice.Office.Common/Security/Scripting ear:type=”oor:string-list”>
<plug about:name=”SecureURL” about:finalized=”true” about:op=”fuse”/>
</item>

Loading external images

Images from external sources can be embedded into documents. This creates significant risks of phishing and vulnerability exploitation, so this option should be disabled: set BlockUntrustedRefererLinks to true with the finalized tag in the /org.openoffice.Office.Common/Security/Scripting group.

Updating linked data

Linked content loaded in Calc can also be malicious, so updates should be blocked by setting the Link option to 1+finalized in the /org.openoffice.Office.Calc/Content/Update group.

The corresponding setting in Writer has different numeric values for some reason; block it by setting Link to 0+finalized in /org.openoffice.Office.Writer/Content/Update.

Exotic files

To disable loading of Abiword, Hangul Office, StarOffice XML, and other irrelevant formats, set LoadExoticFileFormats to 0 in the /org.openoffice.Office.Common/Security group.

Additionally, any of the 100+ supported file formats can be blocked by setting the Enabled option to false+finalized for any format in the group
/org.openoffice.TypeDetection.Filter/Filters/org.openoffice.TypeDetection.Filter:Filter[‘NAME’].
Replace NAME with the name of the format to be blocked.

System authentication

LibreOffice applications can automatically access external URLs using the credentials of the current user, potentially leading to credential leakage. To disable this behavior, set an empty list in the AuthenticateUsingSystemCredentials option:

<item oor:path=”/org.openoffice.Office.Common/Passwords”>
<prop oor:name=”AuthenticateUsingSystemCredentials” oor:finalized=”true” over:op=”fuse” ear:type=”oor:string-list”/>
</item>

Installing extensions

It’s recommended to disable user installation of extensions and allow extensions to be added only centrally through administrator privileges: set DisableExtensionInstallation to true+finalized in the /org.openoffice.Office.ExtensionManager/ExtensionSecurity group.

To centralize the removal of extensions and disable the ability to do this manually by the user, set DisableExtensionRemoval to true+finalized in the same group.

Updates

LibreOffice applications automatically check for updates, and prompt the user to install them. If updates and patches are managed centrally within the organization, this option can be disabled by setting AutoCheckEnabled to false+finalized in the /org.openoffice.Office.Jobs/Jobs/org.openoffice.Office.Jobs:Job[‘UpdateCheck’]/Arguments group.

Installation of fonts, language packs, and databases (Linux only)

Although these additions may seem harmless, for security reasons, automatic installation should be disabled. Set the EnableFontInstallation, EnableLangpackInstallation, and EnableBaseInstallation options to false+finalized in the /org.openoffice.Office.Common/PackageKit group.

Disable telemetry

Set the CollectUsageInformation and CrashReport options to false+finalized in the /org.openoffice.Office.Common/Misc group.

Document-signing certificates (Linux only)

By default, any folder can be chosen for the NSS database, which stores certificates. This isn’t secure and can lead to certificate leaks from uncontrolled locations. The administrator should specify a storage location designated by the organization using the CertDir option:

<item oor:path=”/org.openoffice.Office.Common/Security/Scripting”>
<prop over:name=”CertDir” over:op=”fuse” over:type=”xs:string”/>
</item>

Removing personal data (document author data)

If document distribution cannot be controlled, author data often needs to be hidden. To make LibreOffice remove this data when saving a document, add the RemovePersonalInfoOnSaving setting (true+finalized) in the /org.openoffice.Office.Common/Security/Scripting group.

This mode makes it more complicated to collaborate on a document as it’s harder to identify the author of any changes, so it’s not suitable for all organizational roles.

BSI also recommends disabling the saving of full PGP keys in signed documents, as they also contain author’s personal data: set MinimalKeyExport to true+finalized in the /org.openoffice.Office.Common/Security/OpenPGP group.

Settings to lock

These settings are initially set to be secure, but should be prevented from being changed by adding the finalized attribute.

Group name
Setting name
Value

/org.openoffice.Inet/Settings
ooInetProxyType
1

/org.openoffice.Office.Common/Security/Scripting
HyperlinksWithCtrlClick
true

/org.openoffice.Office.Security/Hyperlinks
Open
1

/org.openoffice.Office.Common/Security/Scripting
CheckDocumentEvents
true

/org.openoffice.Office.Common/Passwords
UseStorage
False

/org.openoffice.Office.Common/Passwords
TrySystemCredentialsFirst
false

/org.openoffice.Office.Jobs/Jobs/org.openoffice.Office.Jobs:Job[‘UpdateCheck’]/Arguments
ExtendedUserAgent
false

Additional protective layers

On any platform, users may encounter targeted cyberattacks and malicious documents. Therefore, secure OS and office suite settings should be complemented by a comprehensive set of layered defense measures:

Multi-factor authentication
Centralized access rights management
Mandatory EDR agent on all workstations and servers
Centralized security event monitoring using SIEM, or preferably XDR solutions.

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Episode 360 of the transatlantic cable podcast kicks off with news that Nvidia are on the receiving end of a class-action law-suit, alleging that they scraped YouTube videos without creators’ consent.  From there, the team discuss news around Taylor Swift AI images being shared by Donald Trump and an additional story around how photography is quickly being swamped by generative A.I.

To close, the team discuss a story around how your humble television is being invaded by advertisers.

If you like what you heard, please consider subscribing.

Nvidia Sued for Scraping YouTube After 404 Media Investigation
Swift Could Sue Trump Under State Law for Fake AI Endorsement
The AI photo editing era is here, and it’s every person for themselves
Your TV set has become a digital billboard

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All software applications, including operating systems, contain vulnerabilities, so regular updates to patch them are a cornerstone of cybersecurity. The researchers who invented the Windows Downdate attack targeted this very update mechanism, aiming to stealthily roll back a fully updated Windows system to an older version containing vulnerable files and services. This leaves the system exposed to well-known exploits and deep-level compromise — including the hypervisor and secure kernel. Worse, standard update and system-health checks will report that everything’s up to date and fine.

Attack mechanism

The researchers actually found two separate flaws with slightly different operating mechanisms. One vulnerability — assigned the CVE-2024-21302 ID and dubbed Downdate — is based on a flaw in the update installation process: the downloaded update components are controlled, protected from modification, and digitally signed, but at one of the intermediate installation stages (between reboots), the update procedure creates and then uses a file containing a list of planned actions (pending.xml). If attackers are able to create their own version of that file and then add information about it to the registry, Windows Modules Installer service (TrustedInstaller) will execute the instructions in it upon reboot.

In actual fact, the contents of pending.xml do get verified, but it’s done during previous installation stages — TrustedInstaller doesn’t re-verify it. Of course, it’s impossible to write whatever you like to the file and install arbitrary files this way — since they must be signed by Microsoft, but replacing system files with older files developed by Microsoft is quite feasible. This can re-expose the system to long-patched vulnerabilities — including critical ones. Adding the necessary keys related to pending.xml to the registry requires administrator privileges, after which a system reboot must be initiated. However, these are the only significant limitations. This attack doesn’t require elevated privileges (for which Windows dims the display and prompts an admin for additional permission), and most security tools won’t flag the actions performed during the attack as suspicious.

The second vulnerability — CVE-2024-38202 — allows an actor to manipulate the Windows.old folder, where the update system stores the previous Windows installation. Although modifying files in this folder requires special privileges, an attacker with regular user-rights can rename the folder, create a new Windows.old from scratch, and place outdated, vulnerable versions of Windows system files in it. Initiating a system restore then rolls Windows back to the vulnerable installation. Certain privileges are required for system restoration, but these aren’t administrator privileges and are sometimes granted to regular users.

VBS bypass and password theft

Since 2015, the Windows architecture has been redesigned to prevent a Windows kernel compromise leading to that of the whole system. This involves a range of measures collectively known as virtualization-based security (VBS). Among other things, the system hypervisor is used to isolate OS components and create a secure kernel for performing the most sensitive operations, storing passwords, and so on.

To prevent attackers from disabling VBS, Windows can be configured to make this impossible — even with administrator rights. The only way to disable this protection is by rebooting the computer in a special mode and entering a keyboard command. This feature is called a Unified Extensible Firmware Interface (UEFI) lock. The Windows Downdate attack bypasses this restriction as well by replacing files with modified, outdated, and vulnerable versions. VBS doesn’t check system files for up-to-dateness, so they can be substituted with older, vulnerable versions with no detectable signs or error messages. That is, VBS isn’t disabled technically, but the feature no longer performs its security function.

This attack allows for the replacement of secure-kernel and hypervisor files with two-year-old versions containing multiple vulnerabilities whose exploitation leads to privilege escalation. As a result, attackers can gain maximum system privileges, full access to the hypervisor and memory-protection processes, and the ability to easily read credentials, hashed passwords, and also NTLM hashes from memory (which can be used for expanding the network attack).

Protection against Downdate

Microsoft was informed of the Downdate vulnerabilities in February 2024, but it wasn’t until August that details were released as part of its monthly Patch Tuesday rollout. Fixing the bugs proved to be a tough task fraught with side effects — including the crashing of some Windows systems. Therefore, instead of rushing to publish another patch, Microsoft for now has simply issued some tips to mitigate the risks. These include the following:

Auditing users authorized to perform system-restore and update operations, minimizing the number of such users, and revoking permissions where possible.
Implementing access control lists (ACL/DACL) to restrict access to, and modification of update files.
Configuring event monitoring for instances where elevated privileges are used to modify or replace update files — this could be an indicator of vulnerability exploitation.
Similarly, monitoring the modification and replacement of files associated with the VBS subsystem and system-file backups.

Monitoring these events using SIEM and EDR is relatively straightforward. However, false positives can be expected, so distinguishing legitimate sysadmin activity from that of hackers ultimately falls to the security team.

All of the above applies not only to physical, but also virtual Windows machines in cloud environments. For virtual machines in Azure, we also advise tracking unusual attempts to log in with administrator credentials. Enable MFA and change the credentials in case such an attempt is detected.

One other, more drastic tip: revoke administrator privileges for employees who don’t need them, and mandate that genuine administrators (i) only perform administrative actions under their respective account, and (ii) use a separate account for other work.

Risky fixes

For those looking for more security, Microsoft offers the update KB5042562, which mitigates the severity of CVE-2024-21302. With this installed, outdated versions of VBS system files are added to the revoked list and can no longer be run on an updated computer. This policy (SkuSiPolicy.p7b) is applied at the UEFI level, so when using it you need to update not only the OS but also backup removable boot media. It’s also important to be aware that rollback to older installations of Windows would no longer be possible. What’s more, the update forcibly activates the User Mode Code Integrity (UMCI) feature, which itself can cause compatibility and performance issues.

In general, administrators are advised to carefully weigh the risks, and thoroughly study the procedure and its potential side effects. Going forward, Microsoft promises to release patches and additional security measures for all relevant versions of Windows — up to Windows 10, version 1507, and Windows Server 2016.

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