On 23.05.2023 21:54, Felix Rubio wrote:
Hi everybody, I am trying to understand something, and after looking around I have not found any explicit answer. Maybe somebody in this list can shed some light on the matter? I have a laptop in which I am setting up the boot process through systemd-boot, and this works. Now, I'd like to give a try to enable Secure Boot so that the whole boot sequence is protected against tampering. As I am still learning about the technology, I prefer to land on the use of shim/MOK. For what I have read, the sequence should be: 1. Install a version of shim signed with MS keys. 2. On that same folder copy systemd-bootx64.efi, renamed to grubx64.efi (as shim seems to work only with Grub as 2nd stage loader). 3. Sign the kernel with the key for which the certificate has been enrolled in MOK. 4. Reboot, enroll the keys and... voila. So far, so good... until we hit the initramfs wall: the efi's and kernel signatures are verified, but not that of the initramfs. I have seen that grub2 does not do it (it relies in GPG signatures, in which seems to be a workaround), and I have not found any place stating that systemd-boot
GPG is independent alternative method of verifying files and most certainly not a workaround (it was implemented in grub2 long before Secure Boot support).
does it. I have seen however, some steering towards the use of UKI... but this comes with its own problems about out-of-tree kernel modules and so. So, the question is: why the kernel image gets verified but not the initramfs? Is this mandated by some standard, or is an engineering decision?
Kernel image has verifiable origin (it is signed by the same entity that provides your distribution). It is static and does not change on end user system which makes it possible to sign by maintainers of distribution by a secret key that is hopefully kept secret.
initrd is volatile, it is usually generated on the same system where it should be verified which means the key to sign it must be kept on the same system as well. Which makes it more probable that secret key will be leaked if system is compromised. And leaked secret key allows installing an arbitrary malware as part of initrd.
Measured boot does not have this problem. If you encrypt your root and only allow decrypting if initrd (and kernel and any other data used during boot) has known content then initrd will be implicitly verified and if it is changed system simply fails to boot. This does not require any key management or storing any persistent secret on end system. Downside is that it requires TPM (or some other tamper resistant way to store hashes) so not universally applicable.
Thank you very much!
