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[Verifying my OpenPGP key: openpgp4fpr:AC6AF1F838DF3DCC2E47A6CF1E892DB2A5F84479]

  • 6 Posts
  • 6 Comments
Joined 4 years ago
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Cake day: January 28th, 2021

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  • Servers use Linux

    The server, desktop, and mobile computing models are all quite different. The traditional desktop model involves giving programs the same user privileges and giving them free reign over all a user’s data; the server model splits programs into different unprivileged users isolated from each other, with one admin account configuring everything; the mobile model gives programs private storage and ensures that programs can’t read each others’ data and need permission to read shared storage. Each has unique tradeoffs.

    macOS has been adopting safeguards to sandbox programs with fewer privileges than what’s available to a user account; Windows has been lagging behind but has made some progress (I’m less familiar with the Windows side of this). On Linux, all modern user-friendly attempts to bring sandboxing to the desktop (Flatpak and Snap are what I’m thinking of) allow programs opt into sandboxing. The OS doesn’t force all programs to run with minimum privileges by default having users control escalating user-level privileges; if you chmod +x a file, it gets all user-level privileges by default. Windows is…somewhat similar in this regard, I admit. But Windows’ sandboxing options–UXP and the Windows Sandbox–are more airtight than Flatpak (I’m more familiar with Flatpak than Snap, as I have some unrelated fundamental disagreements with Snap’s design).

    I think Flatpak has the potential to improve a lot: it can make existing permissions enabled at run-time so that filesystem-wide sandboxing only gets enabled when a program tries to bypass a portal (most of the “filesystem=*” apps can work well without it, and some only need it for certain tasks), and the current seccomp filter can be made a “privileged execution” permission with the default filters offering fine-grained ioctl filtering and toggleable W^X + W!->X enforcement. The versions of JavaScriptCore, GJS, Electron, Java, and LuaJIT used by runtimes and apps can be patched to run in JITless mode unless e.g. an envvar for “privileged execution” is detected. I’ve voiced some of these suggestions to the devs before.

    My favorite (and current) distro is Fedora. If Flatpak makes these improvements, Fedora lands FS-verity in Fedora 37, Fedora lands dm-verity in Silverblue/Kinoite, and we get some implementation of verified boot that actually lets users control the signing key: I personally wouldn’t consider Fedora “insecure” anymore. Though I’d still find it to be a bit problematic because of Systemd. I wasn’t convinced by Madaidan’s brief criticisms of Systemd; I prefer this series of posts that outlines issues in Systemd’s design and shows how past exploits could have been proactively (instead of reactively) avoided:

    Systemd exposes nice functionality and I genuinely enjoy using it, but its underlying architecture doesn’t provide a lot of protections against itself. The reason I bring it up when distros like Alpine and Gentoo exist is that the distro I currently think best combines the traditional desktop model with some hardening–Fedora Silverblue/Kinoite–uses it.

    QubesOS is based on Linux

    QubesOS is based on Linux, but it isn’t in the same category as a traditional desktop Linux distribution. Like Android and ChromeOS, it significantly alters the desktop model by compartmentalizing everything into Xen hypervisors. I brought it up to show how it’s possible to “make Linux secure” but in doing so you’d deviate heavily from a standard distribution. Although Qubes is based on Linux, its devs feel more comfortable calling it a “Xen distribution” to highlight its differences from other Linux distributions.

    Here’s an exhaustive list of the proprietary software on my machine:

    This is a defeatist attitude and meaningless excuse.

    I only brought this up in response to the bad-faith argument you previously made:

    I think you have gotten influenced by madaidan’s grift because you use a lot of closed source tools and want to justify it to yourself as safe.

    I don’t use any closed-sourced tools on my personal machine beyone hardware support, emulated games, and webapps I have to run for online classes. Since you seem to be arguing in bad faith, I don’t think I’ll engage further. Best of luck.


  • He is a security grifter that recommends Windows and MacOS over Linux for some twisted security purposes.

    Windows Enterprise and macOS are ahead of Linux’s exploit mitigations. Madaidan wasn’t claiming that Windows and macOS are the right OSes for you, or that Linux is too insecure for it to be a good fit for your threat model; he was only claiming that Windows and macOS have stronger defenses available.

    QubesOS would definitely give Windows and macOS a run for their money, if you use it correctly. Ultimately, Fuchsia is probably going to eat their lunch security-wise; its capabilities system is incredibly well done and its controls over dynamic code execution put it even ahead of Android. I’d be interested in seeing Zircon- or Fuchsia-based distros in the future.

    When it comes to privacy: I fully agree that the default settings of Windows, macOS, Chrome, and others are really bad. And I don’t think “but it’s configurable” excuses them: https://pleroma.envs.net/notice/AB6w0HTyU9KiUX7dsu

    I think you have gotten influenced by madaidan’s grift because you use a lot of closed source tools and want to justify it to yourself as safe.

    Here’s an exhaustive list of the proprietary software on my machine:

    • Microcode
    • Intel subsystems for my processor (ME, AMT is disabled. My next CPU hopefully won’t be x86_64 because the research I did on ME and AMD Secure Technology gave me nightmares).
    • Non-executable firmware
    • Patent-encumbered media codecs with open-source implementations (AVC/H.264, HEVC/H.265). This should be FLOSS but algorithms are patented; commercial use and distribution can be subject to royalties.
    • Web apps I’m required to use and would rather avoid (e.g. the web version of Zoom for school).
    • Some Nintendo 3DS games I play in a FLOSS emulator (Citra). Sandboxed, ofc.

    That’s it. I don’t even have proprietary drivers. I’m strongly against proprietary software on ideological grounds. If you want to know more about my setup, I’ve made my dotfiles available.


  • And… you cannot study the closed source software.

    Sure you can. I went over several example.

    I freely admit that this leaves you dependent on a vendor for fixes, and that certain vendors like oracle can be horrible to work with (seriously check out that link, it’s hilarious). My previous articles on FLOSS being an important mitigation against user domestication are relevant here.

    Can you, with complete certainty, confidently assert the closed source software is more secure? How is it secure? Is it also a piece of software not invading your privacy? Security is not the origin of privacy, and security is not merely regarding its own resilience as standalone code to resist break-in attempts. This whole thing is not just a simple two way relation, but more like a magnetic field generated by a magnet itself. I am sure you understand that.

    I can’t confidently assert anything with complete certainty regardless of source model, and you shouldn’t trust anyone who says they can.

    I can somewhat confidently say that, for instance, Google Chrome (Google’s proprietary browser based on the open-source Chromium) is more secure than most Webkit2GTK browsers. The vast majority of Webkit2gtk-based browsers don’t even fully enable enable sandboxing (webkit_web_context_set_sandbox_enabled).

    I can even more confidently say that Google Chrome is more secure than Pale Moon. In fact, most browsers are more secure than Pale Moon.

    To determine if a piece of software invades privacy, see if it phones home. Use something like Wireshark to inspect what it sends. Web browsers make it easy to save key logs to decrypt packets. Don’t stop there; there are other techniques I mentioned to work out the edge cases. A great option is using a decompiler.

    Certain forms of security are necessary for certain levels of privacy. Other forms of security are less relevant for certain levels of privacy, depending on your threat model. There’s a bit of a venn-diagram effect going on here.

    FLOSS being less secure when analysed with whitebox methods assures where it stands on security.

    Sure, but don’t stop at whitebox methods. You should use black-box methods too. I outlined why in the article and used a Linux vuln as a prototypical example.

    This will always be untrue for closed source software, therefore the assertation that closed source software is more secure, is itself uncertain.

    You’re making a lot of blanket, absolute statements. Closed-source software can be analyzed, and I described how to do it. This is more true for closed-source software that documents its architecture; such documentation can then be tested.

    Moreover, FOSS devs are idealistic and generally have good moral inclinations towards the community and in the wild there are hardly observations that tell FOSS devs have been out there maliciously sitting with honeypots and mousetraps. This has long been untrue for closed source devs, where only a handful examples exist where closed source software devs have been against end user exploitation. (Some common examples in Android I see are Rikka Apps (AppOps), Glasswire, MiXplorer, Wavelet, many XDA apps, Bouncer, Nova Launcher, SD Maid, emulators vetted at r/emulation.)

    I am in full agreement with this paragraph. There is a mind-numbing amount of proprietary shitware out there. That’s why, even if I was only interested in security, I wouldn’t consider running proprietary software that hasn’t been researched.


  • I am tired of people acting like blackbox analysis is same as whitebox analysis.

    I was very explicit that the two types of analysis are not the same. I repeatedly explained the merits of source code, and the limitations of black-box analysis. I also devoted an entire section to make an example of Intel ME because it showed both the strengths and the limitations of dynamic analysis and binary analysis.

    My point was only that people can study proprietary software, and vulnerability discovery (beyond low-hanging fruit typically caught by e.g. static code analysis) is slanted towards black-box approaches. We should conclude that software is secure through study, not by checking the source model.

    Edit: I liked that last sentence I wrote so I added it to the conclusion. Diff.

    Lots of FLOSS is less secure than proprietary counterparts, and vice versa. The difference is that proprietary counterparts make us entirely dependent on the vendor for most things, including security. I wrote two articles exploring that issue, both of which I linked near the top. I think you might like them ;).

    Now, if a piece of proprietary software doesn’t document its architecture, makes heavy use of obfuscation techniques in critical places, and is very large/complex: I’d be very unlikely to consider it secure enough for most purposes.




  • I wrote about both issues, and why Matrix isn’t a perfect solution, previously: part 1, part 2. Starring WhatsApp, Firefox, Signal, XMPP, Email, and Matrix.

    Also discussed on Lemmy: part 1, part 2.

    Signal’s problem is being a closed platform; Matrix suffers primarily from complexity. Both enable dependence on a single small group, and therefore enable user domestication. That being said, Matrix is considerably less bad than Signal.

    For large public rooms, IRC continues to be the best option. All its issues are client-side; IRCv3 supports history, multiple devices, authentication without NickServ, and even typing notifications. All these features are supported on Oragono. For small, private E2EE rooms, all existing solutions have major trade-offs.