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systemd/docs/BOOT_LOADER_INTERFACE.md

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---
title: Boot Loader Interface
category: Booting
layout: default
SPDX-License-Identifier: LGPL-2.1-or-later
---
# The Boot Loader Interface
systemd can interface with the boot loader to receive performance data and
other information, and pass control information. This is only supported on EFI
systems. Data is transferred between the boot loader and systemd in EFI
variables. All EFI variables use the vendor UUID
`4a67b082-0a4c-41cf-b6c7-440b29bb8c4f`.
* The EFI Variable `LoaderTimeInitUSec` contains the timestamp in microseconds
when the loader was initialized. This value is the time spent in the firmware
for initialization, it is formatted as numeric, NUL-terminated, decimal
string, in UTF-16.
* The EFI Variable `LoaderTimeExecUSec` contains the timestamp in microseconds
when the loader finished its work and is about to execute the kernel. The
time spent in the loader is the difference between `LoaderTimeExecUSec` and
`LoaderTimeInitUSec`. This value is formatted the same way as
`LoaderTimeInitUSec`.
* The EFI variable `LoaderDevicePartUUID` contains the partition GUID of the
ESP the boot loader was run from formatted as NUL-terminated UTF16 string, in
normal GUID syntax.
* The EFI variable `LoaderConfigTimeout` contains the boot menu timeout
currently in use. It may be modified both by the boot loader and by the
host. The value should be formatted as numeric, NUL-terminated, decimal
string, in UTF-16. The time is specified in seconds. In addition some
non-numeric string values are also accepted. A value of `menu-force`
will disable the timeout and show the menu indefinitely. If set to `0` or
`menu-hidden` the default entry is booted immediately without showing a menu.
sd-boot: add way to disable the 100ms delay when timeout=0 Currently we have a 100ms delay which allows for people to enter/show the boot menu even when timeout is set to zero. In a handful of cases, that may not be needed - both in terms of access policy, as well as latency. For example: the option to provide the boot menu may be hidden behind an "expert only" UX in the OS, to avoid end users from accidentally entering it. In addition, the current 100ms input polling may cause unexpected additional delays in the boot. Some example numbers from my SteamDeck: - boot counting/rename/flush doubles 300us -> 600us - seed/hash setup doubles 900us -> 1800us - kernel/image load gets ~40% slower 107ms -> 167ms It's not entirely clear why the UEFI calls gets slower, nevertheless the information in itself proves useful. This commit introduces a new option "menu-disabled", which omits the 100ms delay. The option is documented throughout the manual pages as well as the Boot Loader Specification. v2: - use STR_IN_SET v3: - drop erroneous whitespace v4: - add a new LoaderFeature bit, - don't change ABI keep TIMEOUT_* tokens the same - move new token in the 64bit range, update API and storage for it - change inc/dec behaviour to TIMEOUT_MIN : TIMEOUT_MENU_FORCE - user cannot opt-in from sd-boot itself, add assert_not_reached() v5: - s/Menu disablement control/Menu can be disabled/ - rewrap comments to 109 - use SYNTHETIC_ERRNO(EOPNOTSUPP) Signed-off-by: Emil Velikov <emil.velikov@collabora.com>
2023-10-04 14:55:52 +03:00
Unless a value of `menu-disabled` is set, the boot loader should provide a
way to interrupt this by for example listening for key presses for a brief
moment before booting.
* Similarly, the EFI variable `LoaderConfigTimeoutOneShot` contains a boot menu
timeout for a single following boot. It is set by the OS in order to request
display of the boot menu on the following boot. When set overrides
`LoaderConfigTimeout`. It is removed automatically after being read by the
boot loader, to ensure it only takes effect a single time. This value is
formatted the same way as `LoaderConfigTimeout`. If set to `0` the boot menu
timeout is turned off, and the menu is shown indefinitely.
* The EFI variable `LoaderEntries` may contain a series of boot loader entry
identifiers, one after the other, each individually NUL terminated. This may
be used to let the OS know which boot menu entries were discovered by the
boot loader. A boot loader entry identifier should be a short, non-empty
alphanumeric string (possibly containing `-`, too). The list should be in the
order the entries are shown on screen during boot. See below regarding a
recommended vocabulary for boot loader entry identifiers.
* The EFI variable `LoaderEntryDefault` contains the default boot loader entry
to use. It contains a NUL-terminated boot loader entry identifier.
* Similarly, the EFI variable `LoaderEntryOneShot` contains the default boot
loader entry to use for a single following boot. It is set by the OS in order
to request booting into a specific menu entry on the following boot. When set
overrides `LoaderEntryDefault`. It is removed automatically after being read
by the boot loader, to ensure it only takes effect a single time. This value
is formatted the same way as `LoaderEntryDefault`.
* The EFI variable `LoaderEntrySelected` contains the boot loader entry
identifier that was booted. It is set by the boot loader and read by
the OS in order to identify which entry has been used for the current boot.
* The EFI variable `LoaderFeatures` contains a 64-bit unsigned integer with a
number of flags bits that are set by the boot loader and passed to the OS and
indicate the features the boot loader supports. Specifically, the following
bits are defined:
* `1 << 0` → The boot loader honours `LoaderConfigTimeout` when set.
* `1 << 1` → The boot loader honours `LoaderConfigTimeoutOneShot` when set.
* `1 << 2` → The boot loader honours `LoaderEntryDefault` when set.
* `1 << 3` → The boot loader honours `LoaderEntryOneShot` when set.
2024-02-23 11:56:00 +03:00
* `1 << 4` → The boot loader supports boot counting as described in [Automatic Boot Assessment](AUTOMATIC_BOOT_ASSESSMENT).
* `1 << 5` → The boot loader supports looking for boot menu entries in the Extended Boot Loader Partition.
2019-09-04 19:21:14 +03:00
* `1 << 6` → The boot loader supports passing a random seed to the OS.
sd-boot: add way to disable the 100ms delay when timeout=0 Currently we have a 100ms delay which allows for people to enter/show the boot menu even when timeout is set to zero. In a handful of cases, that may not be needed - both in terms of access policy, as well as latency. For example: the option to provide the boot menu may be hidden behind an "expert only" UX in the OS, to avoid end users from accidentally entering it. In addition, the current 100ms input polling may cause unexpected additional delays in the boot. Some example numbers from my SteamDeck: - boot counting/rename/flush doubles 300us -> 600us - seed/hash setup doubles 900us -> 1800us - kernel/image load gets ~40% slower 107ms -> 167ms It's not entirely clear why the UEFI calls gets slower, nevertheless the information in itself proves useful. This commit introduces a new option "menu-disabled", which omits the 100ms delay. The option is documented throughout the manual pages as well as the Boot Loader Specification. v2: - use STR_IN_SET v3: - drop erroneous whitespace v4: - add a new LoaderFeature bit, - don't change ABI keep TIMEOUT_* tokens the same - move new token in the 64bit range, update API and storage for it - change inc/dec behaviour to TIMEOUT_MIN : TIMEOUT_MENU_FORCE - user cannot opt-in from sd-boot itself, add assert_not_reached() v5: - s/Menu disablement control/Menu can be disabled/ - rewrap comments to 109 - use SYNTHETIC_ERRNO(EOPNOTSUPP) Signed-off-by: Emil Velikov <emil.velikov@collabora.com>
2023-10-04 14:55:52 +03:00
* `1 << 13` → The boot loader honours `menu-disabled` option when set.
* The EFI variable `LoaderSystemToken` contains binary random data,
persistently set by the OS installer. Boot loaders that support passing
random seeds to the OS should use this data and combine it with the random
seed file read from the ESP. By combining this random data with the random
seed read off the disk before generating a seed to pass to the OS and a new
seed to store in the ESP the boot loader can protect itself from situations
where "golden" OS images that include a random seed are replicated and used
on multiple systems. Since the EFI variable storage is usually independent
(i.e. in physical NVRAM) of the ESP file system storage, and only the latter
is part of "golden" OS images, this ensures that different systems still come
up with different random seeds. Note that the `LoaderSystemToken` is
generally only written once, by the OS installer, and is usually not touched
after that.
If `LoaderTimeInitUSec` and `LoaderTimeExecUSec` are set, `systemd-analyze`
will include them in its boot-time analysis. If `LoaderDevicePartUUID` is set,
systemd will mount the ESP that was used for the boot to `/boot`, but only if
that directory is empty, and only if no other file systems are mounted
there. The `systemctl reboot --boot-loader-entry=…` and `systemctl reboot
--boot-loader-menu=…` commands rely on the `LoaderFeatures` ,
`LoaderConfigTimeoutOneShot`, `LoaderEntries`, `LoaderEntryOneShot`
boot: implement kernel EFI RNG seed protocol with proper hashing Rather than passing seeds up to userspace via EFI variables, pass seeds directly to the kernel's EFI stub loader, via LINUX_EFI_RANDOM_SEED_TABLE_GUID. EFI variables can potentially leak and suffer from forward secrecy issues, and processing these with userspace means that they are initialized much too late in boot to be useful. In contrast, LINUX_EFI_RANDOM_SEED_TABLE_GUID uses EFI configuration tables, and so is hidden from userspace entirely, and is parsed extremely early on by the kernel, so that every single call to get_random_bytes() by the kernel is seeded. In order to do this properly, we use a bit more robust hashing scheme, and make sure that each input is properly memzeroed out after use. The scheme is: key = HASH(LABEL || sizeof(input1) || input1 || ... || sizeof(inputN) || inputN) new_disk_seed = HASH(key || 0) seed_for_linux = HASH(key || 1) The various inputs are: - LINUX_EFI_RANDOM_SEED_TABLE_GUID from prior bootloaders - 256 bits of seed from EFI's RNG - The (immutable) system token, from its EFI variable - The prior on-disk seed - The UEFI monotonic counter - A timestamp This also adjusts the secure boot semantics, so that the operation is only aborted if it's not possible to get random bytes from EFI's RNG or a prior boot stage. With the proper hashing scheme, this should make boot seeds safe even on secure boot. There is currently a bug in Linux's EFI stub in which if the EFI stub manages to generate random bytes on its own using EFI's RNG, it will ignore what the bootloader passes. That's annoying, but it means that either way, via systemd-boot or via EFI stub's mechanism, the RNG *does* get initialized in a good safe way. And this bug is now fixed in the efi.git tree, and will hopefully be backported to older kernels. As the kernel recommends, the resultant seeds are 256 bits and are allocated using pool memory of type EfiACPIReclaimMemory, so that it gets freed at the right moment in boot.
2022-11-09 14:44:37 +03:00
variables.
## Boot Loader Entry Identifiers
While boot loader entries may be named relatively freely, it's highly
recommended to follow the following rules when picking identifiers for the
entries, so that programs (and users) can derive basic context and meaning from
the identifiers as passed in `LoaderEntries`, `LoaderEntryDefault`,
`LoaderEntryOneShot`, `LoaderEntrySelected`, and possibly show nicely localized
names for them in UIs.
1. When boot loader entries are defined through the
[Boot Loader Specification](https://uapi-group.org/specifications/specs/boot_loader_specification/)
files, the identifier should be derived directly from the file name,
but with the `.conf` (Type #1 snippets) or `.efi` (Type #2 images)
suffix removed.
2. Entries automatically discovered by the boot loader (as opposed to being
configured in configuration files) should generally have an identifier
prefixed with `auto-`.
3. Boot menu entries referring to Microsoft Windows installations should either
use the identifier `windows` or use the `windows-` prefix for the
identifier. If a menu entry is automatically discovered, it should be
prefixed with `auto-`, see above (Example: this means an automatically
discovered Windows installation might have the identifier `auto-windows` or
`auto-windows-10` or so.).
4. Similarly, boot menu entries referring to Apple macOS installations should
use the identifier `osx` or one that is prefixed with `osx-`. If such an
entry is automatically discovered by the boot loader use `auto-osx` as
identifier, or `auto-osx-` as prefix for the identifier, see above.
5. If a boot menu entry encapsulates the EFI shell program, it should use the
identifier `efi-shell` (or when automatically discovered: `auto-efi-shell`,
see above).
6. If a boot menu entry encapsulates a reboot into EFI firmware setup feature,
it should use the identifier `reboot-to-firmware-setup` (or
`auto-reboot-to-firmware-setup` in case it is automatically discovered).
## Links
[Boot Loader Specification](https://uapi-group.org/specifications/specs/boot_loader_specification)<br>
[Discoverable Partitions Specification](https://uapi-group.org/specifications/specs/discoverable_partitions_specification)<br>
[`systemd-boot(7)`](https://www.freedesktop.org/software/systemd/man/systemd-boot.html)<br>
[`bootctl(1)`](https://www.freedesktop.org/software/systemd/man/bootctl.html)<br>
[`systemd-gpt-auto-generator(8)`](https://www.freedesktop.org/software/systemd/man/systemd-gpt-auto-generator.html)