254 lines
14 KiB
Markdown
254 lines
14 KiB
Markdown
---
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title: "Secure Boot: this is not the protection we are looking for"
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slug: "secure-boot-not"
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description: "An article trying to prove that Secure Boot is often failing to provide any kind of meaningful protection, mostly because of the number of stuff that can go wrong."
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date: 2022-11-30T00:00:00+00:00
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type: posts
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draft: false
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categories:
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- security
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tags:
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- tpm
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- secure boot
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- sysadmin
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- linux
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lang: en
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---
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Before being a technology, secure boot is an English expression. But, what does
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it mean to boot securely? What are we trying to achieve and to protect?
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First, we want user data protection from a secure system. User data is really
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any piece of data a user might display or edit, including the obvious office
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documents but also configuration files, databases, downloaded files, log files,
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user commands, etc. These data must be protected in confidentiality. For this,
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the system must ensure that these data are protected at rest, when the system
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is shutdown. However, this is not enough, since access from unauthorized
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software could leak the data, for instance over the network or by copying it on
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an external removable drive. Hence, a secure system should only run authorized
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software.
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## Secure Boot, the technology
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Secure Boot[^spec] helps running only authorized software on a machine. It
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does so by bootstrapping the security of the system at boot time, by verifying
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signatures on various software components, before giving way to other
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technologies to keep the system secure, later on. Secure boot works by
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authorizing only select executables to be run. Authorized executables are
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signed using public cryptography, and the keys used to verify those signatures
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are stored securely in UEFI "databases".
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[^spec]: [UEFI Specifications](https://uefi.org/specs/access)
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UEFI is the successor of the now nearly defunct BIOS. It is an interface
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between the operating system and the manufacturer platform, a firmware, that
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runs very early on most modern systems. The platform is responsible of, among
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many other things, executing the bootloader (for instance, Grub or
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systemd-boot). Generally, the bootloader then starts an operating system. In
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the case of GNU/Systemd/Linux, the bootloader runs the Linux kernel, which
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shuts down all UEFI Boot Services, before dropping its privileges and then
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doing "Linux stuff" (like starting the userland part of the operating system).
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This privilege drop is very important because this is what ensures that no code
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past that point is able to tamper with the UEFI sensitive information,
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including UEFI variables, which contains sensitive data.
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Secure Boot aims at securing "everything" that is executed prior to that
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privilege drop. Once the privileges are drop, Secure Boot is done and it is up
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to the operating system to extend that integrity/authenticity protection and
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ensure that only authorized software is run. Most Linux distros do not even try
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to do it, although there are notable exceptions (Chrome OS, Android, just to
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name a few). If we run one of the distros that do not leverage technologies
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such as dm-verity, fs-verity (with signatures) or Linux IMA (Integrity
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Management Architecture), then Secure Boot protected the boot integrity for
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basically nothing, because the security chain is broken by the operating
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system, and user data is at risk from possibly any tainted userland executable.
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Nevertheless, ANSSI, the French Infosec Agency recommends in its GNU/Linux
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security guide[^linuxguide] to enable Secure Boot (R3) for all systems
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requiring medium security level (level 2 out of 4, 1 being the minimal
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requirements and 4 being for highly secure systems). Meanwhile, using a Unified
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Kernel Image to bundle the Linux kernel with a initramfs into a single
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executable that can be verified by Secure Boot is only recommended[^R6] for
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highly secure systems (security level 4 out of 4). No recommendation is ever
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done about using one of the aforementioned integrity features to ensure
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operating system integrity.
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[^linuxguide]: no English version yet. [French version](https://www.ssi.gouv.fr/uploads/2019/02/fr_np_linux_configuration-v2.0.pdf)
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[^R6]: "Protect command line parameters and initramfs with Secure Boot"
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Interestingly, a poll on the fediverse[^poll] revealed that 89% of the
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respondants thinks that Secure Boot is necessary for intermediate security
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level, and 45% even think that it should be a minimum requirement.
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This article is a strong push-back against ANSSI "recommendation", and it
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attempts to prove that it is not only useless but incoherent and misleading.
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[^poll]: [Mastodon poll](https://infosec.exchange/@x_cli/109348532363333158)
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## Signature verification and default public keys
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Secure boot relies on a set of public keys to verify authorized software
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authenticity. By default, most vendors ship Microsoft public keys. These keys
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sign all Microsoft Windows version, of course, but to avoid a monopoly, other
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executables were signed. The list is ought to be short (and unfortunately, it
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is not) because with each signature and authorized software, the attack surface
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grows and the probability of a vulnerability raises. Several were already found
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in the recent past (e.g. CVE-2020-10713[^CVE-2020-10713],
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CVE-2022-34301[^CVE-2022-34301], CVE-2022-34302[^CVE-2022-34302],
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CVE-2022-34303[^CVE-2022-34303].
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[^CVE-2020-10713]: [CVE-2020-10713](https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2020-10713)
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[^CVE-2022-34301]: [CVE-2022-34301](https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2022-34301)
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[^CVE-2022-34302]: [CVE-2022-34302](https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2022-34302)
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[^CVE-2022-34303]: [CVE-2022-34303](https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2022-34303)
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For this reason, many software still require that Secure Boot be deactivated,
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including firmware updates by some manufacturers, including
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Intel[^intelUpgrade] or Lenovo[^lenovoUpgrade].
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[^intelUpgrade]: [Intel UEFI Flash BIOS Update Instruction](https://www.intel.com/content/dam/support/us/en/documents/mini-pcs/UEFI-Flash-BIOS-Update-Instructions.pdf)
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[^lenovoUpgrade]: [Lenovo flash BIOS with UEFI tool](https://support.lenovo.com/us/en/solutions/ht118103-flash-bios-with-uefi-tool-ideacentre-stick-300)
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Grub and the kernels are not directly authorized by Microsoft, as it would
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require for each and every single version to be signed individually by
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Microsoft. Instead, a binary called Shim[^shim] was developed. This rather
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small, auditable, innocuous-looking program is signed by Microsoft. Its role is
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basically that of a trojan horse (or a security pivot, depending on the way you
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look at it). Indeed, its only purpose is to cryptographically verify the
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authenticity of any executable. However, this time, the list of public keys
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used to verify these executables is not directly under the control of
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Microsoft. These public keys are either built in Shim itself or stored in a EFI
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variable serving as a database.
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[^shim]: [shim source code](https://github.com/rhboot/shim)
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Additionally, shim public key list can be altered by any user able to prove
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"presence". This is the case of any user using the local console or using a BMC
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for remote console access. Once a new public key enrolled, all executables
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verifiable by that key can run in the UEFI privileged mode, and for instance
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create a persistent backdoor in the bootstrapping code of the machine.
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If this was not enough, users able to prove "presence" can also disable shim
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verification of authorized software. This means that shim can be used to have
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the system believe that Secure Boot was used to bootstrap security, while
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untrusted code was ultimately run within the UEFI privileged mode.
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Hence, thanks to shim, just about any signed or unsigned, trusted or untrusted
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executable can be validated by proxy by Secure Boot using Microsoft keys.
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And this conclusion signs (pun intended) the second incoherence in ANSSI
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recommendations. Indeed, they recommend replacing Microsoft keys by our own set
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of keys only for highly secure security level (R4). This means that all systems
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with intermediate (2/4) and enhanced (3/4) security levels will have the false
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sense of security of running Secure Boot while exposing themselves to attackers
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capable of proving "presence".
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For what it is worth, shim does provide a way secure all operations, including
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disabling verification or enrolling new keys by setting a password on shim's
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MOK (Machine Owner Keys) Manager[^mokpass]. However, the feature is mostly
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unused because no Linux distro enables it (it requires user interaction during
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the boot procedure) and system administrators often mistake the MOK Manager
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password, which secures the access to the MOK Manager as a whole, with the
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password that is asked when running mokutil commands (including `--import` and
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`--disable-verification`), which is just a password used to confirm the will of
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the user in the MOK Manager. The author of this article failed to find a single
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tutorial or article discussing the necessity of setting a MOK Manager for a
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Secure Boot. ANSSI also failed to recommend that. Most interestingly, setting a
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MOK Manager password is recommended even for Windows administrators that have
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no intention of ever running Linux, because MOK Manager is one of
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the executables signed by the Microsoft keys.
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[^mokpass]: The command is `mokutil --password`. Please consider using it.
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## Using our own set of Secure Boot keys (PK and KEK)
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Since replacing the Microsoft keys and signing only authorized binaries (i.e.
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our own Unified Kernel Image and specifically not shim) is an option, why not
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do that? It just requires that the system administrators replace the Secure
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Boot keys. The question of who controls the private key and the signature
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process is entirely up to whether the signed executable is altered or not by
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the system administrator. Distros could ship public keys and Unified Kernel
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Images instead of relying on Shim. If we run our own kernel, as recommended by
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ANSSI (R15 to R27), then we need to handle the private key and the signature
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process ourselves.
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With a Unified Kernel Image signed and verified by Secure Boot, we are now sure
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that only our code is executed, and we can safely ask for the user passphrase
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to unlock the LUKS container. This way, user data is protected at rest, and
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accessed only by authorized software. Cool. Except it is not.
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First, as mentioned earlier, the only thing that we verified is that the
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Unified Kernel Image is authentic. That kernel must then verify the operating
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system to ensure that only verified software is run. This requires
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cryptographic verification of every single executable (binaries, scripts and
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executable configuration files (because... yeah... that's a thing)) in the
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operating system. This can be achieved if we, at minimum, do the following:
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* use a read-only filesystem for our partitions containing executable code,
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enforced using dm-verity, or fs-verity with file signature or Linux IMA, or
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something similar;
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* use the noexec mount option on data partitions;
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* modify command interpreters to ensure they do not execute scripts from mount
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points with noexec nor from STDIN;
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* prevent writable memory from ever getting executed, by patching the kernel;
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* ensure that no executable configuration file is writable.
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Welcome in Wonderland, Alice.
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Ok, but let's assume we go down that rabbit hole... are we secure yet?
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No. No, we are not.
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Because there is no way of telling if our Secure Boot implementation is tainted
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by an attacker or not. Indeed, someone could have flashed our UEFI firmware
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before we enabled Secure Boot. Or they could have disabled it, flashed and
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reenabled it, if we did not have a UEFI administration password at some point.
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Or they could have abused shim when we were using the default keys to flash
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UEFI.
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## Nirvana Fallacy much?
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So, if Secure Boot is not a good answer, especially against an attacker capable
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of physical access or remote access through a BMC, what is? Is there a better
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solution?
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Well, to the best of the author knowledge, there is one: using a TPM. Using a
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TPM will not necessarily prevent an attacker from tainting the firmware. It
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will not necessarily prevent booting untrusted and unverified executables. What
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a TPM can give us is the ability to unseal a LUKS passphrase and get access to
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user data if and only if the cryptographically verified right version of UEFI
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firmware, Unified Kernel Image and operating system image have been booted.
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This is based on PCR policies, that ties the sealed passphrase to a particular
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signed set of executables measured by the TPM. This approach ensures user data
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confidentiality at rest and the authenticity of the executables that are on
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disk during boot. Of course, it does not prevent executing writable memory, nor
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user data flagged as executable, including scripts, and executable
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configuration files. And of course, having a signed set of policies means
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handling a private key and designing a signature procedure. There is no free
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lunch. Sorry.
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However, using a TPM offers the same security level against attackers with
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physical access, attackers with remote access through a BMC, and a rogue system
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administrator, and that is something that Secure Boot cannot brag about.
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## Conclusion
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So there you have it: recommending idly Secure Boot for all systems requiring
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intermediate security level accomplishes nothing, except maybe giving more work
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to system administrators that are recompiling their kernel, while offering
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exactly no measurable security against many threats if UEFI Administrative
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password and MOK Manager passwords are not set. This is especially true for
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laptop systems where physical access cannot be prevented for obvious reasons.
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For servers in colocation, the risk of physical access is not null. And finally
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for many servers, the risk of a rogue employee somewhere in the supply chain,
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or the maintenance chain cannot be easily ruled out.
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