This is both true, and also useless: pretty much any E2E system is falling under this definition.
By definition you can't protect yourself from the entity that provides you the software you use, because you have now way to guarantee that they aren't going to backdoor you.
That doesn't mean it's snake oil though, as the entity you want protection against is generally not the software provider but a third party. Using e2e from a US-based entity means you are prone to spying from the US government, but at least you know you're reasonably secure against the IRGC, the Chinese intelligence service, the FSB, and so on.
It also means you are safe from data leaks, which are by far the most common threat today.
No system can be secure unconditionally, it's always secure under a particular threat model. And in practice “the attacker is able to deploy arbitrary code on your behalf for an extended period of time without being detected ” is a much narrower attack surface than “the attacker is able to obtain read-only access to your DB or your backups for at least a few minutes”. In the former case, the encryption being broken is also the least of your concern, as you've basically given remote access to all of your user's devices at this point…
There are limits to this of course. You can’t buy a TACLANE[1], but you can buy many of the other products[2] USG uses to protect its own classified information.
[1] https://gdmissionsystems.com/encryption/taclane-network-encr...
[2] https://www.nsa.gov/resources/Commercial-Solutions-for-Class...
A more modern example is probably the NSA aggressively pushing[3] for replacing classical encryption with post-quantum encryption, rather than taking the more conservative and probably-more-secure approach of layering the two - while at the same time mandating the use of two layers of those same algorithms for their own use[4]!
[0]: https://en.wikipedia.org/wiki/NOBUS
[1]: https://en.wikipedia.org/wiki/Clipper_chip
[2]: https://en.wikipedia.org/wiki/Dual_EC_DRBG
[3]: https://blog.cr.yp.to/20251004-weakened.html
[4]: https://defense-solutions.curtisswright.com/capabilities/tec...
There is no hard evidence that it was backdoored.
The problem with these examples is that they weren't used in national security systems, which are the systems for which NSA has a legislated defensive responsibility.
Clipper was designed for use by the public; it was not intended to ever be used to protect classified (or even sensitive unclassified) information at all.
Likewise with Dual_EC_DRBG. The CSfC component requirements drew from the Common Criteria Protection Profiles, where Dual_EC_DRBG was never an option.
You don't need E2E for that, using https/TLS for transport and servers hosted in the US would be enough.
Data breaches happen literally every day.
> in practice “the attacker is able to deploy arbitrary code on your behalf for an extended period of time without being detected ” is a much narrower attack surface than “the attacker is able to obtain read-only access to your DB or your backups for at least a few minutes”. In the former case, the encryption being broken is also the least of your concern, as you've basically given remote access to all of your user's devices at this point…
Data breach occur every day, rootkits being covertly deployed in production apps for a substantial period are much rarer. E2ee only protects against the former, like a safety belt only prevent you from frontal shocks. Nobody would say they are snake oil because of that.
But with repro builds and system transparency, hiding backdoors is impractical.
On other hand its quite natural, security is not really getting you direct revenue so business is least motivated in investing it or say continuously investing in it. The ones that do are doing partial lip service for most part.
If the software is open source and you only install new versions after their source code has been audited, you should be ok.
That's not completely true. If I can control when (and if!) the software updates and if there is some kind of vetting process to verify that the version I'm currently running does not contain a backdoor, I can treat it like a third party with respect to the server.
I agree with you though that most current software that are made to auto-update at any time without any oversight do not fall under this umbrella. Web apps definitely don't fall under it.
This would be extremely difficult, I would say impossible from a practical standpoint.
This. The author is dismissing the whole web-based cryptography, or any end-to-end cryptography for that matter, on the basis of a one-dimension analysis.
Not necessarily. I push for e2ee everywhere I can for a completely different reason: when (not “if”, “when“) we get breached, we cannot leak sensitive data we don't have.
There are levels to this (hermetic/reproducible builds & attestations, as one example). In fact, TFA is harsh for the only case it wants to make an example out of, WhatsApp Web:
Code Verify works in partnership with Cloudflare, a web infrastructure and security company, to provide independent, third-party, transparent verification of the code you're being served on WhatsApp Web. We hope this gives at-risk users peace of mind.
https://blog.cloudflare.com/cloudflare-verifies-code-whatsap... & https://engineering.fb.com/2022/03/10/security/code-verify/This is not true. I can build Signal from source from GitHub, and use Signal-the-service with the client (which did not come from Signal, but GitHub/my compiler).
Many cryptosystems are like this. In any case, if you are getting something from the App Store, you can get it once and disable autoupdates, which prevents the service provider (presuming they are the same as the people who published the app) from backdooring you at some point in the future. Alternately, even with updates, unless Apple is colluding with them to serve only you* a specific backdoored app, you can at least be reasonably confident that it's not specifically backdooring only you* in an undetectable fashion.
Sure, but can you find an NSA-designed backdoor in the source code?
> you can get it once and disable autoupdates
Try doing that with Signal, and you'll be unable to connect to the main network in just a few days because you get out of sync. Also, what do you do if there's a high severity CVE on the program? You still don't update or you re-audit all the new code?
What you describe may be possible for an intelligence agency, but completely out of reach for an individual.
> unless Apple is colluding with them
Given the most likely adversary is the US intelligence with a warrant, it's absolutely not far fetched to assume that in your threat model.
> you can at least be reasonably confident that it's not specifically backdooring only you
That's not really reassuring…
Because that what quite literally the claim I was arguing with in the first place.
The way I responded to one particular example “what if I download Signal and compile it myself” is just that a particular example, not a shift in argument.
If you think there's no trust assumption in the distribution of software, feel free to provide actual arguments to refute that argument of mine, because so far your comments have been disappointingly lacking in substance.
> Sure, but can you find an NSA-designed backdoor in the source code?
You're moving the goalpost. They were responding to the claim suggesting it's impossible to get non-Signal provided signal.
>> you can get it once and disable autoupdates
> Try doing that with Signal, and you'll be unable to connect to the main network in just a few days because you get out of sync.
That's demonstrably false. On one of my idle/backup phones I'm using Signal 8.8.2, released in April 2026, almost 3 full months ago. It can not only connect to the network but everything works, with every contact.
You might think of the official Signal client expiration, but that's client side (meaning that you can compile and use the version that doesn't have it) and..... 90 days, not "a few".
I don't have a concrete number for the server side of enforcement though (minimumVersions seems to be populated at start time, with the defaults not committed to the repo). It's not entirely unreasonable to assume that the lowest official supported version is the one that introduced the concept of usernames, and the only meaningful capability test is SPQR.
> Also, what do you do if there's a high severity CVE on the program? You still don't update or you re-audit all the new code?
I think disabling auto update was shown as a possible strategy against a silent, targeted auto update. Not a way to remain protected against the general CVEs.
Non sequitur.
That was never my claim. The claim is that you cannot protect youself from Signal being malicious if Signal is the maker of the software. Compiling the software yourself doesn't help against the kind of adversary in the threat model.
> That's demonstrably false. On one of my idle/backup phones I'm using Signal 8.8.2, released in April 2026, almost 3 full months ago. It can not only connect to the network but everything works, with every contact.
Lucky you, you only need to fully audit the codebase every 3 months.
I'm using the Signal apk directly so I'm painfully aware of the frequency of the breakages.
> I think disabling auto update was shown as a possible strategy against a silent, targeted auto update. Not a way to remain protected against the general CVEs.
I don't think you understand my point. I'm not talking about the CVE being exploited against you. The CVE will just push you to download the compromised update, breaking your “security through lack of update” policy.
The definition is quite clear. It does not apply when the implementation is not distributed by the same entity that creates it for example. There are other related issues but the message here is that web based cryptography has a particular weakness when it comes to things like end to end encrypted messaging which makes it so bad as to be worthless.
How can you be sure that the entity distributing the software didn't backdoor it?
> the message here is that web based cryptography has a particular weakness when it comes to things like end to end encrypted messaging
There's literally no substance about that claim in TFA.
Framing this in terms of governmental espionage is nonsensical. Using e2e from a US-based entity makes you completely sure that the US government is spying on you, because they assert direct control over the software you are running. There is no venue to seek justice against an unlawful contract if the government is in on it.
You should instead take a step back into reality and consider data misuse by normal non-government actors. Facebook claiming e2e encryption is a contractual matter, that you can litigate. That's where the actual protection is. That's also why real business demands not "unbreakable encryption" but reliable marker for access and tampering. It is much more useful to have a record of who accessed the data, than a claim that it's impossible.
The E2E encryption is not protecting you, it's protecting the company providing the software.
The only thing that is legit is the local use of PGP. But it's a shame we don't really progress much.
Isn't this conflating encryption with trust? Of course whoever claims to encrypt your data needs to be trustworthy, and whether they actually are is another matter, but If my app allows you to generate a client side key, export it and use it to encrypt data client side and we only get the encrypted data, that is verifiably valid encryption.
I could be malicious and also send a copy of your actual plaintext to the server as well, but that is trivial to check (unless I'm being targeted and I am the only user that gets the malicious code, still, I can check). It's a risky proposition for an organization with vested interest in being seen as pro privacy.
But I get it, different conversation if the government coerces you, and the outcome depends on your bank account and ability to handle pressure.
Absolutely, and the claim is somewhere between nonsense and pedantry bordering on nonsense.
The exact same thing is true for, say, Signal. The provider delivers the client, and they aggressively block non-official clients from participating. So the “ends” in end-to-end are ultimately controlled by Signal. But as long as you trust the Signal company not to insert a backdoor into your client, it’s still true that the company can’t read your texts.
The host could inject malicious JavaScript from the host or change libraries but I feel like this is an avoidable problem because it can be audited much more easily than expecting users to audit JavaScript every time. People could even build known, trusted, web frontends. So I think there are mitigations if not ways to assure the browser is running trusted code.
The article argues that Signal is an incoherent cryptosystem, because they ship the E2E-encrypting Signal client (and could, hence, backdoor it) that should protect me, the user, against their own infrastructure snooping on me.
As I understand the definition, we would not have an incoherent cryptosystem if I used a third-party client on Signal's infrastructure. Said Non-Signal client would implement E2E encryption, and use the Signal infrastructure, so the entity running the infrastructure is different from the entity providing the client. But is this any better?
Couldn't “Non-Signal Corp.” be coerced by the government (or decide to build a backdoor for their own gain) just as easily as “Signal”?
So I don't think it matters if the entity distributing the client is the same as the one running the infrastructure. It matters if I trust the client. How to implement this (audits, OSS, version pinning, ...) is still an open question to me.
still this wouldn't guarantee that all the other nodes are not compromised
(Said tongue-in-cheek, I don’t know if there’s other comparable systems out there)
E2E makes it less likely that your information will get hacked and reduces the risk that employees will access your information.
The reality is that these security claims are generally subject to internal audit and would need company wide collusion and the risk of a whistleblower or disgruntled former employee if they were violated provides some level of protection that a large tech company offering of e2e doesn’t mean some level of benefit from the user compared to perfect encryption security.
for this to work in practice it needs to be paired with reproducible builds, open source and either p2p or server choice (use signal.mydomain.net instead of signal.org). but these are all things that already exist and none of them is really hard to set up. the harder problem is distributing community block lists of bad package versions but that can be done with atproto or simple ublock style filter files.
i think the real bottleneck for adoption is that the only browser with built in ipfs support is brave, the one thats full of crypto ads and affiliate link fraud. i dont know if firefox would ever take it up or we need to build a brand new browser. or find a way to do it one layer down with a system service.
Also, on iOS, almost everyone has app autoupdates turned on because that's the default.
This reminds me Telegram, which promises to be secure, but requires giving it my phone number, which is the most insecure thing one can do.
The solution obviously is to go out-of-band:
> When a user visits a website that has enrolled in WEBCAT, before the site can load the content is checked against a signed manifest to ensure that it has not been tampered with (more on enrollment later). If everything checks out, the page loads normally. If, however, any content does not match what’s expected, the page load is aborted and a warning is displayed, protecting the user from potentially malicious content before it can execute.
[0]: https://securedrop.org/news/introducing-webcat-web-based-cod...
[1]: https://securedrop.org/news/browser-based-cryptography/
It's on the level of "you can't trust your OS unless you wrote it yourself" -righteous sounding but utterly stupid in practice
Articles like this remind me that non-devs think "end-to-end encrypted" means it's always the case and they can't turn it off at will. This is not the case.
If web-based encryption is snake oil, then science-based medicine is also snake oil, because you trust your doctor not to secretly give you sugar pills instead of the real thing. In fact, this argument applies even more strongly to medication, because I can't really determine what a pill does, but I can determine what an app or website does and what it sends to the server.
This effect was seen in the Apple vs FBI incident described in the article. The public perception of Apple as a brave defender of user privacy was greatly increased due to that dispute. For all we know, the FBI was in on the conspiracy. In return they might receive the fruits of such surveillance with the only limitation that they would have to disguise the source with parallel construction[2].
1. Aren't E2EE systems designed to prevent decryption of content already created in the past sitting on the vendor's servers? Yes, the vendor could go rogue, but, assuming they currently have implemented E2EE right, it means any change to the client can only compromise content created in the future from that point onward, no? So why is the article implying Apple could have provided a back-doored iOS to bypass the encryption for existing content?
2. I also don't find the argument that E2EE is only a legal trick fully convincing. There are several other incentives for a vendor to implement it apart from avoiding legal issues: preventing insider abuse, reducing liability, improving customer trust, and resisting mass surveillance
These are real engineering motivations. The threat model is not: "Protect you if <vendor> becomes actively malicious tomorrow." Its more like "Protect messages stored on <Vendor>'s servers from attackers, employees, hackers, routine legal requests, and passive surveillance."
* preventing insider abuse * reducing liability * improving customer trust * resisting mass surveillance
A sophisticated actor might as well also control the application that ends up on my device. It does not have to be the same delivery mechanism as long as I did not write it myself.
So all cryptography is snake oil?
___
I mean I kinda sorta get the point and there would be some merit to discuss there, but the weird framing makes that very hard to do.
Of course it's easier to break web e2ee if you are for example cloudflare compared with someone also having to compromise the Debian repos.
But that's not what snake oil means.
Yes, but it's a whole lot of extra steps spread across multiple independent parties, each of them adds large delays to the actions and increasing the chance that it is discovered long before it ends up on the users machine.
When you hack GPG it will take years before it trickles down into every Linux distribution, especially LTS releases. And ideally, you want an encryption protocol, not one app, thus you have some people running GPG, some running Sequoia PGP and some running OpenPGP.js. If somebody fiddles with the encryption, different clients won't be able to decode the messages anymore and it will be clear pretty quickly that something is wrong.
Meanwhile on the Web or smartphones, you remove or backdoor the encryption, everybody gets auto updated to the latest version and nobody will know that something went wrong.
The xz utils hack got slurped up into sid before it was discovered by a researcher's performance regression in ssh. IIRC the hacked test file didn't even need to be added to the upstream source tree because Debian was blithely downloading release tarballs from Github. No evil Debian maintainer needed.
It's funny that when speculating about Debian's security you forget an actual state-level attack that got code into sid, but when speculating about Signal's insecurity in another thread you're quite happy to imagine potential state-level attacks.
Of course, still orders of magnitude harder than just modifying the js bundle, but not a counter-example.
Snake oil is just a fundamentally wrong label for the issues OP is seeing, even though those issues are of course real and relevant.
I think what makes the Web special is precisely that there are different browsers beyond Chromium. If the Web was Chrome I would tend to agree but even though popular I do not think it is fair to conflate it to be the Web.
My take is that you should trust provider (developer, hoster) of said encryption app to send you actual implementation, not something that looks like the real deal, but does not encrypt anything. From a regular user's point of view: you can not inspect what you run (due to technical reasons, that on the web anything can be downloaded and executed at any moment, swapping implementation on the fly. And due to skills needed to actually read and understand executed scripts), so you can only believe and trust. At which point usual TLS is surely enough.
"A cryptosystem is incoherent if its implementation is distributed by the same entity which it purports to secure against."
What is the cryptosystem then on the Web? Who is the entity? It's not the server or the Website so I don't see what's left except the browser and browser vendor.
Without which TLS is not gonna work.
The article is arguing that in practice you could just send your "encrypted" communications to the browser vendor, or one of the governments on the certificate root list, or someone else in the distribution chain, and have them be the middle man. The security properties of your communications would be the same. Hence "snake oil".
Things like stapling don't change this much, or reduce to TOFU.
Your argument is a bit like saying TLS protects plain-text passwords in transit, so there is no need to store them in hashed form in the database.
Some might call this a “cryptographic innovation.” I call it “the technical outsourcing of legal disclaimers.” Unfortunately, I don’t seem to have a Harvard Law School legal team on my side.
The article's argument is a bit like saying TLS protects plain-text passwords in transit, so there is no need to store them in hashed form in the database.
Sure, the article makes good arguments about the trust that is still implicit in E2EE, but it goes too far in its dismissal of it.
This means that, in practice, iMessage is not e2ee.
Before you say "But what about Advanced Data Protection that enables e2ee for iCloud Backup?" - virtually nobody has this on, Apple prohibits you from turning it on in the UK, and even if you enable it - the people you iMessage with don't, so your conversations are in their backups. This means that if either endpoint of the iMessage conversation is in the UK, and both parties have iCloud Backup enabled (the default), then your iMessages are not e2ee as a non-endpoint has an escrowed copy of the plaintext or keys.
Also no OS integrated system that does this for you automatically / conveniently has ever existed that was widely adopted because that application would have the ability to read all of your private communication, and impossible to install on an uncracked phone.
Still it would take literally minutes to vibe code an app that sits in front of a WhatsApp client and automatically handles these things. Maybe the future is just to write it yourself (not the security) so you can trust it and it’s convenient.