UEFI-Shell

This repository contains pre-built UEFI Shell binary images, generated from official EDK2 stable releases.

Usage

These images are provided in the form of a bootable ISO, in order to make them easy to use with boot media creators such as Rufus.

However, these can also readily used by:

• Partitioning and formatting a media, such as a USB Flash drive, using a FAT file system.
• Extracting the ISO content as is, onto the FAT partition.

Once you have done that, and provided that your machine is set to boot from removable media (and runs a UEFI firmware that uses one of the architectures supported by the release), it should automatically boot into the UEFI Shell.

Note that Secure Boot must be disabled for a UEFI Shell media to boot, as Microsoft does not allow an external UEFI Shell to be signed for Secure Boot.

Binary validation

These binaries are built in a fully transparent manner, in order to provide you with complete assurance that they do not contain anything malicious.

To validate this claim, you can perform the following:

1. Locate the build action for the ISO you downloaded under https://github.com/pbatard/UEFI-Shell/actions. For instance, for the 21H1 release, this would be https://github.com/pbatard/UEFI-Shell/actions/runs/1160237413.
2. Click on build to access the build log, and then look at the Checkout repository and submodules task. The last line for that task provides the SHA-1 of the repository commit that was used for the build process (for 21H1 that would be 19803c2b2183849fc3a4d6f08cc3c0549232df0c).
3. Append that SHA-1 to https://github.com/pbatard/UEFI-Shell/commit/ to validate that you end up with one of the public commits that were pushed to this repository. This validates that the build was not triggered by a "hidden" commit, that would perform something malicious, and that we would later delete, since it is impossible for anyone without an army of supercomputers to alter a git commit in order to "fake" a specific SHA-1.
   NB: You don't have to take our word for that last claim. Just google "SHA-1 collision" and also look into the measures that git is taking to switch to SHA-256 so as to make the possibility of collision impossible.
4. At this stage, you have assurance that the commit that was used to build the binary is a public one. However, you must also further validate that the EDK2 source that was used for the build is also the public one that is published from https://github.com/tianocore/edk2, and not some private potentially malicious copy. To accomplish that, click the Browse Files button on the page you got from the URL that was constructed above and the click on the edk2 @ ##### link that you see in the repository tree. For instance, for 21H1, that link will be labelled edk2 @ e1999b2.
5. Validate that this link takes you to a public commit from https://github.com/tianocore/edk2. Once you have done that, then you have validated that, not only the build cannot have been triggered by a hidden commit but also that the EDK2 source for the UEFI Shell that is produced by the build cannot have come from anywhere else but the public EDK2 repository.
6. If you are familiar enough with the build process, you should now look at the GitHub actions .yml from the commit that was used to trigger the build to also validate that it is not doing anything suspiscious (such as discarding the built executables to replace them with pre-built malicious ones downloaded from a third-party server). Again, because you have already validated, with 100% certainty, that all the steps that are used for the build can only have come from a public commit which everyone has access to, it would simply be impossible for any such behaviour not to appear plainly in the .yml.
7. At this stage, you should have total confidence that the build process did produce binaries that can be trusted to have been built only from the public unmodified EDK2 UEFI Shell source. Therefore, the one last item to check is to validate that the binaries proposed under this project's Release page are the actual binaries that were produced from the build, rather than some malicious replacements (since the owner of any GitHub project has the ability to delete and replace release files). This last step is very easy to accomplish however: As part of the build process, we make sure to also display the SHA-256 for all of the UEFI binaries as well as for the ISO images being generated.
   Thus, depending on whether you extracted individual .efi files, or are working directly with a .iso, you can find the relevant SHA-256 displayed either under the Display SHA-256 step or the Generate ISO images step within the build log (and you should of course have validated that the GitHub Actions' .yml that was used as part of the build was indeed set to perform an actual computation of the SHA-256 from the generated files, as opposed to mimicking the display of an SHA-256 computation in order to trick someone looking only at the log into thinking that a malicious file published under Releases, and that was not generated from the automated build process, did come from the build process).
8. Compare the SHA-256 from the build log with the one from the .efi or .iso you downloaded, and verify that they are the same.

If you accomplish all the steps above, then you will have established, with absolute certainty, that the binaries that are being published on our Releases page can be trusted not to contain malware (that is, provided you do accept that toolchains like gcc or GitHub employees can be trusted not to insert malware on their own, but this is outside of the scope of the kind of assurance that we can provide here).

And the nice thing is that, because any failure of validation for the points we describe above is very easy to detect, you can rest assured that, even if you do not go through these steps yourself, someone else is likely to, and is bound to say something if we ever are to do anything that looks contrary to our claim that the UEFI Shell binaries published here are 100% trustworthy.