Firmware security

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Scope

This page describes the role of Open Firmware in BitFrost security on XO.

Goals

  1. Run recovery firmware if primary firmware is bad
  2. No access to ok prompt without developer key
  3. Firmware update images must be signed
  4. Boot images must be signed
  5. Unactivated laptops will only boot the activation image
  6. Boot alternate OS image if primary OS image is bad

Files

The files listed below are on NAND FLASH in JFFS2. The zip archives listed below must be created without compression (-n option) and without paths (-j option). Implementation notes and rationale are in italics.

  • Primary images are in /boot, secondary images are in /boot-alt
    At the start of an upgrade process, boot is copied to boot-alt; this doesn't need to be automatic. When upgrade is complete and validated, the upgraded files will be moved automatically to /boot. The automatic substitution requires /boot to be a symlink to the 'real' boot directory. See Early boot for more details on the upgrade process.
  • The activation lease is named "/security/lease.sig".
    The activation lease is in the firmware activation lease format with hashname "sha"
  • The developer key is named "/security/develop.sig".
    The developer key is in the firmware developer key format with hashname "sha"
    Once the developer key has been read for the first time, it is copied by firmware into reserved space in the flash.
  • The normal OS image is in "/boot/runos.zip", containing "data.img" and "data.sig", and "/boot/runrd.zip", containing "data.img" and "data.sig". An activation OS image is in "/boot/actos.zip", containing "data.img" and "data.sig", and "/boot/actrd.zip", containing "data.img" and "data.sig".
    • data.img in runos.zip and actos.zip is one of the load formats that OFW supports, e.g. Linux bzImage
    • data.img in runrd.zip and actrd.zip is a ramdisk image in a format supported by the kernel in runos.zip/actos.zip (typically initramfs)
    • data.sig is in the firmware key format with hashname "sha256"
    • runrd.zip/actrd.zip may be omitted, in which case runos.zip/actos.zip is booted without a ramdisk.
      Rationale: The ramdisk is only used during activation and certain upgrades. As an optimization, we can skip authenticating and loading the ramdisk when it is not needed in order to simplify and speed up boot. In practice runrd.zip is likely to be a symlink which can be easily deleted and recreated when needed.
  • The new firmware image is "/boot/bootfw.zip", containing "data.img" and "data.sig"
    • data.img is the usual OFW image format
    • data.sig is in the firmware key format with two lines, providing both "sha256" and "rmd160" signatures.
  • The backup files in /boot-alt have the same names and are in the same formats as /boot.

On USB flash drive or SD card, the files are as follows:

  • Only one directory, /boot, containing runos.zip, bootfw.zip, and an optional runrd.zip as before
    Security dictates that we boot from an authenticated filesystem. Rather than have OFW authenticate the full USB/SD contents, we'll boot from an authenticated ramdisk, which can then authenticate whatever other files it needs (if any) from the USB/SD drive. For this reason, there should always be a ramdisk, but it may be monolithic with the kernel in runos.zip rather than in a separate runrd.zip file.
    We should be careful to ensure that the files are authenticated after they have been loaded into memory, to prevent attacks involving switching files between authentication and later use.

Process

  1. If OFW fails to come up correctly, a firmware recovery procedure is attempted - (future enhancement).
  2. In the following, the "primary" images are the files in /boot, and the "secondary" images are the files in /boot-alt, unless the "O" gamepad key is held down during boot, in which case the roles reverse: the primary files come from /boot-alt, and the secondary files come from /boot.
  3. If the SPI FLASH lockout latch is already set (as with a warm boot), OFW skips to step 7.
  4. OFW checks for a new firmware image in the /boot directory on an attached USB, then SD, device. If one exists and verifies, OFW reflashes itself and reboots.
    Upgrade USB keys may contain firmware-only upgrades.
  5. OFW checks for a new firmware image in the primary directory in the NAND flash. If one exists and verifies, OFW reflashes itself and reboots.
  6. OFW locks out further SPI FLASH writing with the hardware lock.
  7. If a valid developer key is present, OFW enters non-secure mode, where it behaves as it currently does. Otherwise ...
  8. If the activation key is present and valid, the boot filenames will be runos.zip and (if present) runrd.zip. Otherwise, the boot filenames will be actos.zip and (if present) actrd.zip.
  9. If the activation key is present and valid, we will attempt to verify and boot from the boot files in /boot on an attached USB, then SD, device.
  10. OFW verifies and boots from the boot files in the primary directory.
  11. OFW verifies and boots from the boot files in the secondary directory.
  12. If none of the above booting steps succeed, OFW displays an error screen and halts.
  13. During OS startup, the OS should check the firmware version and if it matches or is greater than the version in the new firmware image file on disk, the OS should delete or rename that file so the firmware won't see it the next time.

Usage notes

  • After boot, userland can determine the source from the OFW device tree - /ofw/chosen/bootpath is the OFW device specifier of the kernel file, /ofw/chosen/ramdisk is the device specifier of the initrd file (if any), and /ofw/chosen/bootargs is the cmdline. This can be used to determine whether activation is needed (actos.zip) or whether booting is being performed from the secondary source (boot-alt/*).
  • Although outside the scope of this spec, there are primary and secondary filesystem roots in /run/a and /run/b corresponding to the kernels in /boot and /boot-alt. /boot/runrd.img will typically be absent to speed boot. However, /boot-alt/runrd.img will typically be required in order to switch to /run/b so that kernel and userland match. When we clone /boot into /boot-alt at the beginning of an upgrade, we link in an appropriate /boot-alt/runrd.img (See Early Boot for more information.)
  • When the alternate kernel is booted and we've switched into /run/b, we can either:
    1. add a /boot/runrd.zip link so that if we reboot into the primary we can switch the filesystem back /run/a, or
    2. Swap /boot and /boot-alt, making future boots start this kernel. This option is preferred. We should ensure that we've done another upgrade before we try to boot into a different kernel again.
  • We will typically use hard or soft links to avoid storing multiple os and ramdisk images. The current status quo is that we have only one kernel and one ramdisk image; the ramdisk looks at how it was invoked to determine whether this is an upgrade, activation, or alternate boot.

Summary

Case File Expiry Signed Object Signature (ASCII) Computation Key Effect on Success
OS/Ramdisk Images /boot{,-alt}/ {run,act}{os,rd}.zip - data.img in .zip data.sig in .zip sha256->rsassa-pss-2048 OLPC_OS_Key Load image
Firmware Images /boot/bootfw.zip - data.img in .zip data.sig in .zip (2 lines) sha256->rsassa-pss-2048, rmd160->rsassa-pkcs-v1_5-2048 OLPC_FW_Key Update firmware
Developer /security/develop.sig - <SN>:<UU>:Time0 keydata on sig line sha256->rsassa-pss-2048 OLPC_DEVELOP_Key Unlock firmware
Lease /security/lease.sig time on sig line <SN>:<UU>:<Expiry> keydata on sig line sha256->rsassa-pss-2048, check time OLPC_LEASE_Key Use runos not actos

Rationale:

  • .sig, not .key, because it contains signatures, not keys
  • no need to reiterate the name for the .img file; it just complicates the code
  • prefer RSASSA-PSS signatures (see PKCS #1) due to known attacks on RSASSA-PKCS [1], [2]
  • ripemd160 protects against false-positive flaws in signature verification algorithm; algorithm choice is constrained by those supported by PKCS #11.
  • "Time0" is in same 16-character format as a legitimate time, but it is ignored.

Notes

  • I am assuming that the primary use of USB/SD boot is to do OS, firmware, or activity upgrades where bandwidth is a limitation. These can easily be done with the mechanism provided by just sticking a (properly signed) "magic upgrade key" into the USB port and power-cycling.
  • USB probing is time-consuming and perilous (although SD is not). At some point (after manufacturing processes are fixed) we'll only try to boot from USB if the 'X' game key is pressed during boot.
  • We could be more user-friendly by detecting "failed boot after linux kernel invocation" in some way, and automatically booting from the backup in this case. This seems like post-FRS work.
  • Firmware RTC *must be UTC*. Quanta must set the RTC to UTC at the factory; antitheft server must sync to UTC during antitheft interaction.


Multiple-Key Support

This section describes an enhancement whereby additional keys can be provided in Open Firmware, so that a deployment can use its own keys, either in place of or in addition to OLPC's keys.

The deployment-specific keys are stored in the manufacturing data area of SPI FLASH, so they are unaffected by firmware updates.

The enhanced version is expected to be deployed in Open Firmware version Q2F03.

Deployment Key Manufacturing Data Tags

Reference: http://wiki.laptop.org/go/Manufacturing_data

(Need to add this info to the mfg data page)

Open Firmware has 5 different public keys:

  1. Developer key - permits full (unsecure) access to all firmware features
  2. Firmware key - permits reflashing the firmware stored in SPI FLASH
  3. Filesystem key - permits rewriting the filesystem on NAND FLASH
  4. OS key - permits the execution of a booted program (typically the OS)
  5. Lease key - permits OS execution in "already activated" mode

An OLPC "master" version of each of those public keys is stored within the Open Firmware image, so that it will be rewritten upon a firmware update.

Deployment-specific keys, if any, are stored in the manufacturing data with tag names as follows. As with all manufacturing data tags, each tag name is two case-sensitive ASCII characters.

  1. Developer key - tag names d0 .. d9 (d for developer)
  2. Firmware key - tag names w0 .. w9 (w for firmWare)
  3. Filesystem key - tag names s0 .. s9 (s for fileSystem)
  4. OS key - tag names o0 .. o9 (oh for OS)
  5. Lease key - tag name l0 .. l9 (ell for lease)

If the numeric suffix is 0, the tag data overrides the corresponding OLPC key, so that the signed object will verify only if it is signed with the deployment-specific key, not if it is signed with the OLPC key.

If the numeric suffix is between 1 and 9 inclusive, each such tag's data provides an additional alternative to the OLPC key, so that the object will verify if it is signed with either the OLPC or any of the deployment keys.

The numbers 1..9 need not appear in sequence or in order; it's okay to have tags s7 and s3, for example. Apart from the special treatment of tag 0, there is no implied precedence of different tag numbers from 1 to 9, since a given signed object will either match one of the keys or it won't.

The keys for the various purposes are independent. You could, for example, have an o0 tag to override the OLPC OS key, s1 and s5 tags to augment the OLPC filesystem key, and no deployment-specific tags for the developer, firmware, and leas keys.

TBD - is there a need for multiple override keys? If so, we could adopt the policy that, if a key X0 exists, then the OLPC key is invalidated, but all the additional keys X1 .. X9 are valid.

The tag data contains the verbatim binary data for the public key. For the current version of the key format, that is 270 bytes. Since that is longer than 127 bytes, the "long data" tag format must be used (OFW's tag creation tools choose a suitable format automatically). The manufacturing data sector in SPI FLASH is 64K bytes, of which only a few hundred are already used, so there is plenty of room for the maximum possible number of deployment keys.

Making New Deployment Keys

The "bios-crypto" code at http://dev.laptop.org/git?p=bios-crypto has tools for making new key pairs and for signing objects with those keys.

To compile the kit, get the source, go into the "build" subdirectory, and type "make".

The file "build/README" tells how to use the various tools to make new keys and to sign objects.

Adding Deployment Keys to Manufacturing Data

To create a manufacturing data tag containing a deployment key, you can use the OFW "add-tag-from-file" command. For example:

 ok add-tag-from-file s1 u:\myfskey.pub

add-tag-from-file will abort with an error message if that tag name already exists.

To delete a deployment key tag, you can use the delete-tag command, for example:

 ok delete-tag s1

Be careful when changing tags to avoid accidental loss of important system information in other tags.

Procedures for Adding Deployment Keys En Masse

For existing customers who want to add deployment keys to existing secure machines without having to get individual developer keys for each machine, OLPC will need to create and sign a special OFW release that injects the new tags into mfg data, then reflashes itself with a normal OFW release.

Hopefully, deployments will eventually work with Quanta to have their special keys installed by the factory. I'm pretty sure that Quanta's existing tools for populating manufacturing data don't support the long-data tag format, so they will either have to enhance those tools or use the built-in OFW mfg-data tools for deployment keys. I recommend the latter, since it took several go-arounds before Quanta's tools worked correctly.

Inspecting Deployment Keys

From OFW, you can use the exiting ".mfg-data" command or "test-all" to view deployment keys. They are displayed as sequences of hex bytes.

From Linux, you can access the deployment keys as files in /ofw/mfg-data . Since the deployment key "files" contain binary data, a hex dump program like "od -x" is convenient for viewing.

Test Plan

  • for device in sd usb nand
    • for X in 's' 'o' 'w' 'd' 'l'
      • scenario 1: No extra keys - Intent - the current status quo should still work
        • object signed with the OLPC key - should succeed
        • object signed with a different key - should fail
        • corrupted object signed with the OLPC key - should fail
      • scenario 2: Override key (X0) in mfg data - Intent - override key should work and block the OLPC key
        • object signed with the OLPC key - should fail
        • object signed with the override key - should succeed
        • corrupted object signed with the override key - should fail
      • scenario 3: Override key (X0) and augment key (X1 .. X9) in mfg data - Intent - override key should block augment keys
        • object signed with the OLPC key - should fail
        • object signed with the override key - should succeed
        • object signed with the augment key - should fail
      • scenario 4: Multiple augment keys (X1 .. X9) in mfg data - Intent - augment keys should work in addition to OLPC key
        • object signed with the OLPC key - should suceed
        • object signed with the first augment key - should succeed
        • object signed with the second augment key - should succeed
        • object signed with a different key - should fail
      • scenario 4a: Different n and m for augment keys Xn and Xm - Intent - it shouldn't matter which numbers from 1..9 are used for augment keys
        • repeat scenario 4 tests with different names for augment keys
      • scenario 4b: Nine different augment keys - Intent - maximum number of augment keys doesn't break anything
        • repeat scenario 4 with nine augment keys

Test the ability to install and remove keys from mfg data - create several new keys, both augment and override. Delete and recreate in various orders. Check attempts to create keys that already exist, deleting the last key, etc. Verify that the mfg data looks correct after each operation.

Check the visibility of the keys from Linux (in /mfg-data).