Merge pull request #23 from edera-dev/azenla/bootloader-interface

feat(integrations): basic bootloader interface support
2025-12-19 15:20:17 +00:00 · 2025-10-30 14:58:04 -04:00
parent fe714cc411 9d3a022e08
commit cfe7088970
14 changed files with 532 additions and 74 deletions
--- a/src/actions/chainload.rs
+++ b/src/actions/chainload.rs
@@ -1,4 +1,5 @@
 use crate::context::SproutContext;
 use crate::integrations::bootloader_interface::BootloaderInterface;
 use crate::utils;
 use crate::utils::media_loader::MediaLoaderHandle;
 use crate::utils::media_loader::constants::linux::LINUX_EFI_INITRD_MEDIA_GUID;
@@ -102,6 +103,10 @@ pub fn chainload(context: Rc<SproutContext>, configuration: &ChainloadConfigurat
        initrd_handle = Some(handle);
    }
    // Mark execution of an entry in the bootloader interface.
    BootloaderInterface::mark_exec(context.root().timer())
        .context("unable to mark execution of boot entry in bootloader interface")?;
    // Start the loaded image.
    // This call might return, or it may pass full control to another image that will never return.
    // Capture the result to ensure we can return an error if the image fails to start, but only
--- a/src/context.rs
+++ b/src/context.rs
@@ -1,5 +1,6 @@
 use crate::actions::ActionDeclaration;
 use crate::options::SproutOptions;
 use crate::platform::timer::PlatformTimer;
 use anyhow::anyhow;
 use anyhow::{Result, bail};
 use std::cmp::Reverse;
@@ -12,22 +13,29 @@ const CONTEXT_FINALIZE_ITERATION_LIMIT: usize = 100;
 /// Declares a root context for Sprout.
 /// This contains data that needs to be shared across Sprout.
 #[derive(Default)]
 pub struct RootContext {
    /// The actions that are available in Sprout.
    actions: BTreeMap<String, ActionDeclaration>,
    /// The device path of the loaded Sprout image.
    loaded_image_path: Option<Box<DevicePath>>,
    /// Platform timer started at the beginning of the boot process.
    timer: PlatformTimer,
    /// The global options of Sprout.
    options: SproutOptions,
 }
 impl RootContext {
    /// Creates a new root context with the `loaded_image_device_path` which will be stored
-    /// in the context for easy access.
+    /// in the context for easy access. We also provide a `timer` which is used to measure elapsed
-    pub fn new(loaded_image_device_path: Box<DevicePath>, options: SproutOptions) -> Self {
+    /// time for the bootloader.
    pub fn new(
        loaded_image_device_path: Box<DevicePath>,
        timer: PlatformTimer,
        options: SproutOptions,
    ) -> Self {
        Self {
            actions: BTreeMap::new(),
            timer,
            loaded_image_path: Some(loaded_image_device_path),
            options,
        }
@@ -43,6 +51,11 @@ impl RootContext {
        &mut self.actions
    }
    /// Access the platform timer that is started at the beginning of the boot process.
    pub fn timer(&self) -> &PlatformTimer {
        &self.timer
    }
    /// Access the device path of the loaded Sprout image.
    pub fn loaded_image_path(&self) -> Result<&DevicePath> {
        self.loaded_image_path
--- a/src/entries.rs
+++ b/src/entries.rs
@@ -28,6 +28,7 @@ pub struct BootableEntry {
    context: Rc<SproutContext>,
    declaration: EntryDeclaration,
    default: bool,
    pin_name: bool,
 }
 impl BootableEntry {
@@ -44,6 +45,7 @@ impl BootableEntry {
            context,
            declaration,
            default: false,
            pin_name: false,
        }
    }
@@ -72,6 +74,11 @@ impl BootableEntry {
        self.default
    }
    /// Fetch whether the entry is pinned, which prevents prefixing.
    pub fn is_pin_name(&self) -> bool {
        self.pin_name
    }
    /// Swap out the context of the entry.
    pub fn swap_context(&mut self, context: Rc<SproutContext>) {
        self.context = context;
@@ -87,6 +94,11 @@ impl BootableEntry {
        self.default = true;
    }
    /// Mark this entry as being pinned, which prevents prefixing.
    pub fn mark_pin_name(&mut self) {
        self.pin_name = true;
    }
    /// Prepend the name of the entry with `prefix`.
    pub fn prepend_name_prefix(&mut self, prefix: &str) {
        self.name.insert_str(0, prefix);
--- a/src/extractors/filesystem_device_match.rs
+++ b/src/extractors/filesystem_device_match.rs
@@ -9,9 +9,7 @@ use uefi::fs::{FileSystem, Path};
 use uefi::proto::device_path::DevicePath;
 use uefi::proto::media::file::{File, FileSystemVolumeLabel};
 use uefi::proto::media::fs::SimpleFileSystem;
-use uefi::proto::media::partition::PartitionInfo;
+use uefi::{CString16, Guid};
 use uefi::{CString16, Guid, Handle};
 use uefi_raw::Status;
 /// The filesystem device match extractor.
 /// This extractor finds a filesystem using some search criteria and returns
@@ -41,48 +39,6 @@ pub struct FilesystemDeviceMatchExtractor {
    pub fallback: Option<String>,
 }
 /// Represents the partition UUIDs for a filesystem.
 struct PartitionIds {
    /// The UUID of the partition.
    partition_uuid: Guid,
    /// The type UUID of the partition.
    type_uuid: Guid,
 }
 /// Fetches the partition UUIDs for the specified filesystem handle.
 fn fetch_partition_uuids(handle: Handle) -> Result<Option<PartitionIds>> {
    // Open the partition info protocol for this handle.
    let partition_info = uefi::boot::open_protocol_exclusive::<PartitionInfo>(handle);
    match partition_info {
        Ok(partition_info) => {
            // GPT partitions have a unique partition GUID.
            // MBR does not.
            if let Some(gpt) = partition_info.gpt_partition_entry() {
                let uuid = gpt.unique_partition_guid;
                let type_uuid = gpt.partition_type_guid;
                Ok(Some(PartitionIds {
                    partition_uuid: uuid,
                    type_uuid: type_uuid.0,
                }))
            } else {
                Ok(None)
            }
        }
        Err(error) => {
            // If the filesystem does not have a partition, that is okay.
            if error.status() == Status::NOT_FOUND || error.status() == Status::UNSUPPORTED {
                Ok(None)
            } else {
                // We should still handle other errors gracefully.
                Err(error).context("unable to open filesystem partition info")?;
                unreachable!()
            }
        }
    }
 }
 /// Extract a filesystem device path using the specified `context` and `extractor` configuration.
 pub fn extract(
    context: Rc<SproutContext>,
@@ -106,30 +62,49 @@ pub fn extract(
        // This defines whether a match has been found.
        let mut has_match = false;
        // Extract the partition info for this filesystem.
        // There is no guarantee that the filesystem has a partition.
        let partition_info =
            fetch_partition_uuids(handle).context("unable to fetch partition info")?;
        // Check if the partition info matches partition uuid criteria.
-        if let Some(ref partition_info) = partition_info
+        if let Some(ref has_partition_uuid) = extractor.has_partition_uuid {
-            && let Some(ref has_partition_uuid) = extractor.has_partition_uuid
+            // Parse the partition uuid from the extractor.
        {
            let parsed_uuid = Guid::from_str(has_partition_uuid)
                .map_err(|e| anyhow!("unable to parse has-partition-uuid: {}", e))?;
-            if partition_info.partition_uuid != parsed_uuid {
+
            // Fetch the root of the device.
            let root = uefi::boot::open_protocol_exclusive::<DevicePath>(handle)
                .context("unable to fetch the device path of the filesystem")?
                .deref()
                .to_boxed();
            // Fetch the partition uuid for this filesystem.
            let partition_uuid = utils::partition_guid(&root, utils::PartitionGuidForm::Partition)
                .context("unable to fetch the partition uuid of the filesystem")?;
            // Compare the partition uuid to the parsed uuid.
            // If it does not match, continue to the next filesystem.
            if partition_uuid != Some(parsed_uuid) {
                continue;
            }
            has_match = true;
        }
        // Check if the partition info matches partition type uuid criteria.
-        if let Some(ref partition_info) = partition_info
+        if let Some(ref has_partition_type_uuid) = extractor.has_partition_type_uuid {
-            && let Some(ref has_partition_type_uuid) = extractor.has_partition_type_uuid
+            // Parse the partition type uuid from the extractor.
        {
            let parsed_uuid = Guid::from_str(has_partition_type_uuid)
                .map_err(|e| anyhow!("unable to parse has-partition-type-uuid: {}", e))?;
-            if partition_info.type_uuid != parsed_uuid {
+
            // Fetch the root of the device.
            let root = uefi::boot::open_protocol_exclusive::<DevicePath>(handle)
                .context("unable to fetch the device path of the filesystem")?
                .deref()
                .to_boxed();
            // Fetch the partition uuid for this filesystem.
            let partition_type_uuid =
                utils::partition_guid(&root, utils::PartitionGuidForm::Partition)
                    .context("unable to fetch the partition uuid of the filesystem")?;
            // Compare the partition type uuid to the parsed uuid.
            // If it does not match, continue to the next filesystem.
            if partition_type_uuid != Some(parsed_uuid) {
                continue;
            }
            has_match = true;
--- a/src/generators/bls.rs
+++ b/src/generators/bls.rs
@@ -83,13 +83,16 @@ pub fn generate(context: Rc<SproutContext>, bls: &BlsConfiguration) -> Result<Ve
        }
        // Get the file name of the filesystem item.
-        let name = entry.file_name().to_string();
+        let mut name = entry.file_name().to_string();
        // Ignore files that are not .conf files.
        if !name.to_lowercase().ends_with(".conf") {
            continue;
        }
        // Remove the .conf extension.
        name.truncate(name.len() - 5);
        // Create a mutable path so we can append the file name to produce the full path.
        let mut full_entry_path = entries_path.to_path_buf();
        full_entry_path.push(entry.file_name());
@@ -125,13 +128,21 @@ pub fn generate(context: Rc<SproutContext>, bls: &BlsConfiguration) -> Result<Ve
        context.set("options", options);
        context.set("initrd", initrd);
-        // Add the entry to the list with a frozen context.
+        // Produce a new bootable entry.
-        entries.push(BootableEntry::new(
+        let mut entry = BootableEntry::new(
            name,
            bls.entry.title.clone(),
            context.freeze(),
            bls.entry.clone(),
-        ));
+        );
        // Pin the entry name to prevent prefixing.
        // This is needed as the bootloader interface requires the name to be
        // the same as the entry file name, minus the .conf extension.
        entry.mark_pin_name();
        // Add the entry to the list with a frozen context.
        entries.push(entry);
    }
    Ok(entries)
--- a/src/integrations.rs
+++ b/src/integrations.rs
@@ -0,0 +1,2 @@
 /// Implements support for the bootloader interface specification.
 pub mod bootloader_interface;
--- a/src/integrations/bootloader_interface.rs
+++ b/src/integrations/bootloader_interface.rs
@@ -0,0 +1,125 @@
 use crate::platform::timer::PlatformTimer;
 use crate::utils::device_path_subpath;
 use anyhow::{Context, Result};
 use uefi::proto::device_path::DevicePath;
 use uefi::{CString16, Guid, guid};
 use uefi_raw::table::runtime::{VariableAttributes, VariableVendor};
 /// The name of the bootloader to tell the system.
 const LOADER_NAME: &str = "Sprout";
 /// Bootloader Interface support.
 pub struct BootloaderInterface;
 impl BootloaderInterface {
    /// Bootloader Interface GUID from https://systemd.io/BOOT_LOADER_INTERFACE
    const VENDOR: VariableVendor = VariableVendor(guid!("4a67b082-0a4c-41cf-b6c7-440b29bb8c4f"));
    /// Tell the system that Sprout was initialized at the current time.
    pub fn mark_init(timer: &PlatformTimer) -> Result<()> {
        Self::mark_time("LoaderTimeInitUSec", timer)
    }
    /// Tell the system that Sprout is about to execute the boot entry.
    pub fn mark_exec(timer: &PlatformTimer) -> Result<()> {
        Self::mark_time("LoaderTimeExecUSec", timer)
    }
    /// Tell the system that Sprout is about to display the menu.
    pub fn mark_menu(timer: &PlatformTimer) -> Result<()> {
        Self::mark_time("LoaderTimeMenuUsec", timer)
    }
    /// Tell the system about the current time as measured by the platform timer.
    /// Sets the variable specified by `key` to the number of microseconds.
    fn mark_time(key: &str, timer: &PlatformTimer) -> Result<()> {
        // Measure the elapsed time since the hardware timer was started.
        let elapsed = timer.elapsed_since_lifetime();
        Self::set_cstr16(key, &elapsed.as_micros().to_string())
    }
    /// Tell the system what loader is being used.
    pub fn set_loader_info() -> Result<()> {
        Self::set_cstr16("LoaderInfo", LOADER_NAME)
    }
    /// Tell the system the relative path to the partition root of the current bootloader.
    pub fn set_loader_path(path: &DevicePath) -> Result<()> {
        let subpath = device_path_subpath(path).context("unable to get loader path subpath")?;
        Self::set_cstr16("LoaderImageIdentifier", &subpath)
    }
    /// Tell the system what the partition GUID of the ESP Sprout was booted from is.
    pub fn set_partition_guid(guid: &Guid) -> Result<()> {
        Self::set_cstr16("LoaderDevicePartUUID", &guid.to_string())
    }
    /// Tell the system what boot entries are available.
    pub fn set_entries<N: AsRef<str>>(entries: impl Iterator<Item = N>) -> Result<()> {
        // Entries are stored as a null-terminated list of CString16 strings back to back.
        // Iterate over the entries and convert them to CString16 placing them into data.
        let mut data = Vec::new();
        for entry in entries {
            // Convert the entry to CString16 little endian.
            let encoded = entry
                .as_ref()
                .encode_utf16()
                .flat_map(|c| c.to_le_bytes())
                .collect::<Vec<u8>>();
            // Write the bytes (including the null terminator) into the data buffer.
            data.extend_from_slice(&encoded);
        }
        Self::set("LoaderEntries", &data)
    }
    /// Tell the system what the default boot entry is.
    pub fn set_default_entry(entry: String) -> Result<()> {
        Self::set_cstr16("LoaderEntryDefault", &entry)
    }
    /// Tell the system what the selected boot entry is.
    pub fn set_selected_entry(entry: String) -> Result<()> {
        Self::set_cstr16("LoaderEntrySelected", &entry)
    }
    /// Tell the system about the UEFI firmware we are running on.
    pub fn set_firmware_info() -> Result<()> {
        // Format the firmware information string into something human-readable.
        let firmware_info = format!(
            "{} {}.{:02}",
            uefi::system::firmware_vendor(),
            uefi::system::firmware_revision() >> 16,
            uefi::system::firmware_revision() & 0xFFFFF,
        );
        Self::set_cstr16("LoaderFirmwareInfo", &firmware_info)?;
        // Format the firmware revision into something human-readable.
        let firmware_type = format!("UEFI {:02}", uefi::system::firmware_revision());
        Self::set_cstr16("LoaderFirmwareType", &firmware_type)
    }
    /// The [VariableAttributes] for bootloader interface variables.
    fn attributes() -> VariableAttributes {
        VariableAttributes::BOOTSERVICE_ACCESS | VariableAttributes::RUNTIME_ACCESS
    }
    /// Set a bootloader interface variable specified by `key` to `value`.
    fn set(key: &str, value: &[u8]) -> Result<()> {
        let name =
            CString16::try_from(key).context("unable to convert variable name to CString16")?;
        uefi::runtime::set_variable(&name, &Self::VENDOR, Self::attributes(), value)
            .with_context(|| format!("unable to set efi variable {}", key))?;
        Ok(())
    }
    /// Set a bootloader interface variable specified by `key` to `value`, converting the value to
    /// a [CString16].
    fn set_cstr16(key: &str, value: &str) -> Result<()> {
        // Encode the value as a CString16 little endian.
        let encoded = value
            .encode_utf16()
            .flat_map(|c| c.to_le_bytes())
            .collect::<Vec<u8>>();
        Self::set(key, &encoded)
    }
 }
--- a/src/main.rs
+++ b/src/main.rs
@@ -1,12 +1,16 @@
 #![doc = include_str!("../README.md")]
 #![feature(uefi_std)]
 extern crate core;
 use crate::config::RootConfiguration;
 use crate::context::{RootContext, SproutContext};
 use crate::entries::BootableEntry;
 use crate::integrations::bootloader_interface::BootloaderInterface;
 use crate::options::SproutOptions;
 use crate::options::parser::OptionsRepresentable;
 use crate::phases::phase;
 use crate::platform::timer::PlatformTimer;
 use crate::utils::PartitionGuidForm;
 use anyhow::{Context, Result, bail};
 use log::{error, info};
 use std::collections::BTreeMap;
@@ -38,9 +42,15 @@ pub mod extractors;
 /// generators: Runtime code that can generate entries with specific values.
 pub mod generators;
 /// platform: Integration or support code for specific hardware platforms.
 pub mod platform;
 /// menu: Display a boot menu to select an entry to boot.
 pub mod menu;
 /// integrations: Code that interacts with other systems.
 pub mod integrations;
 /// phases: Hooks into specific parts of the boot process.
 pub mod phases;
@@ -55,6 +65,21 @@ pub mod utils;
 /// Run Sprout, returning an error if one occurs.
 fn run() -> Result<()> {
    // Start the platform timer.
    let timer = PlatformTimer::start();
    // Mark the initialization of Sprout in the bootloader interface.
    BootloaderInterface::mark_init(&timer)
        .context("unable to mark initialization in bootloader interface")?;
    // Tell the bootloader interface what firmware we are running on.
    BootloaderInterface::set_firmware_info()
        .context("unable to set firmware info in bootloader interface")?;
    // Tell the bootloader interface what loader is being used.
    BootloaderInterface::set_loader_info()
        .context("unable to set loader info in bootloader interface")?;
    // Parse the options to the sprout executable.
    let options = SproutOptions::parse().context("unable to parse options")?;
@@ -69,17 +94,35 @@ fn run() -> Result<()> {
        config::loader::load(&options)?
    };
-    // Load the root context.
+    // Grab the sprout.efi loaded image path.
    // This is done in a block to ensure the release of the LoadedImageDevicePath protocol.
-    let mut root = {
+    let loaded_image_path = {
        let current_image_device_path_protocol = uefi::boot::open_protocol_exclusive::<
            LoadedImageDevicePath,
        >(uefi::boot::image_handle())
        .context("unable to get loaded image device path")?;
-        let loaded_image_path = current_image_device_path_protocol.deref().to_boxed();
+        current_image_device_path_protocol.deref().to_boxed()
        RootContext::new(loaded_image_path, options)
    };
    // Grab the partition GUID of the ESP that sprout was loaded from.
    let loaded_image_partition_guid =
        utils::partition_guid(&loaded_image_path, PartitionGuidForm::Partition)
            .context("unable to retrieve loaded image partition guid")?;
    // Set the partition GUID of the ESP that sprout was loaded from in the bootloader interface.
    if let Some(loaded_image_partition_guid) = loaded_image_partition_guid {
        // Tell the system about the partition GUID.
        BootloaderInterface::set_partition_guid(&loaded_image_partition_guid)
            .context("unable to set partition guid in bootloader interface")?;
    }
    // Tell the bootloader interface what the loaded image path is.
    BootloaderInterface::set_loader_path(&loaded_image_path)
        .context("unable to set loader path in bootloader interface")?;
    // Create the root context.
    let mut root = RootContext::new(loaded_image_path, timer, options);
    // Insert the configuration actions into the root context.
    root.actions_mut().extend(config.actions.clone());
@@ -159,13 +202,17 @@ fn run() -> Result<()> {
    for (name, generator) in config.generators {
        let context = context.fork().freeze();
-        // We will prefix all entries with [name]-.
+        // We will prefix all entries with [name]-, provided the name is not pinned.
        let prefix = format!("{}-", name);
        // Add all the entries generated by the generator to the entry list.
        // The generator specifies the context associated with the entry.
        for mut entry in generators::generate(context.clone(), &generator)? {
-            entry.prepend_name_prefix(&prefix);
+            // If the entry name is not pinned, prepend the name prefix.
            if !entry.is_pin_name() {
                entry.prepend_name_prefix(&prefix);
            }
            entries.push(entry);
        }
    }
@@ -200,6 +247,21 @@ fn run() -> Result<()> {
        entry.mark_default();
    }
    // Iterate over all the entries and tell the bootloader interface what the entries are.
    for entry in &entries {
        // If the entry is the default entry, tell the bootloader interface it is the default.
        if entry.is_default() {
            // Tell the bootloader interface what the default entry is.
            BootloaderInterface::set_default_entry(entry.name().to_string())
                .context("unable to set default entry in bootloader interface")?;
            break;
        }
    }
    // Tell the bootloader interface what entries are available.
    BootloaderInterface::set_entries(entries.iter().map(|entry| entry.name()))
        .context("unable to set entries in bootloader interface")?;
    // Execute the late phase.
    phase(context.clone(), &config.phases.late).context("unable to execute late phase")?;
@@ -223,9 +285,14 @@ fn run() -> Result<()> {
            .context(format!("unable to find entry: {force_boot_entry}"))?
    } else {
        // Delegate to the menu to select an entry to boot.
-        menu::select(menu_timeout, &entries).context("unable to select entry via boot menu")?
+        menu::select(&timer, menu_timeout, &entries)
            .context("unable to select entry via boot menu")?
    };
    // Tell the bootloader interface what the selected entry is.
    BootloaderInterface::set_selected_entry(entry.name().to_string())
        .context("unable to set selected entry in bootloader interface")?;
    // Execute all the actions for the selected entry.
    for action in &entry.declaration().actions {
        let action = entry.context().stamp(action);
--- a/src/menu.rs
+++ b/src/menu.rs
@@ -1,4 +1,6 @@
 use crate::entries::BootableEntry;
 use crate::integrations::bootloader_interface::BootloaderInterface;
 use crate::platform::timer::PlatformTimer;
 use anyhow::{Context, Result, bail};
 use log::info;
 use std::time::Duration;
@@ -162,7 +164,15 @@ fn select_with_input<'a>(
 /// Shows a boot menu to select a bootable entry to boot.
 /// The actual work is done internally in [select_with_input] which is called
 /// within the context of the standard input device.
-pub fn select(timeout: Duration, entries: &[BootableEntry]) -> Result<&BootableEntry> {
+pub fn select<'live>(
    timer: &'live PlatformTimer,
    timeout: Duration,
    entries: &'live [BootableEntry],
 ) -> Result<&'live BootableEntry> {
    // Notify the bootloader interface that we are about to display the menu.
    BootloaderInterface::mark_menu(timer)
        .context("unable to mark menu display in bootloader interface")?;
    // Acquire the standard input device and run the boot menu.
    uefi::system::with_stdin(move |input| select_with_input(input, timeout, entries))
 }
--- a/src/platform.rs
+++ b/src/platform.rs
@@ -0,0 +1,2 @@
 /// timer: Platform timer support.
 pub mod timer;
--- a/src/platform/timer.rs
+++ b/src/platform/timer.rs
@@ -0,0 +1,89 @@
 // Referenced https://github.com/sheroz/tick_counter (MIT license) as a baseline.
 // Architecturally modified to support UEFI and remove x86 (32-bit) support.
 use std::time::Duration;
 /// Support for aarch64 timers.
 #[cfg(target_arch = "aarch64")]
 pub mod aarch64;
 /// Support for x86_64 timers.
 #[cfg(target_arch = "x86_64")]
 pub mod x86_64;
 /// The tick frequency of the platform.
 #[derive(Clone, Copy, Debug, PartialEq, Eq)]
 pub enum TickFrequency {
    /// The platform provides the tick frequency.
    Hardware(u64),
    /// The tick frequency is measured internally.
    Measured(u64, Duration),
 }
 impl TickFrequency {
    /// Acquire the tick frequency reported by the platform.
    fn ticks(&self) -> u64 {
        match self {
            TickFrequency::Hardware(frequency) => *frequency,
            TickFrequency::Measured(frequency, _) => *frequency,
        }
    }
    /// Calculate the nanoseconds represented by a tick.
    fn nanos(&self) -> f64 {
        1.0e9_f64 / (self.ticks() as f64)
    }
    /// Produce a duration from the provided elapsed `ticks` value.
    fn duration(&self, ticks: u64) -> Duration {
        let accuracy = self.nanos();
        let nanos = ticks as f64 * accuracy;
        Duration::from_nanos(nanos as u64)
    }
 }
 /// Acquire the tick value reported by the platform.
 fn arch_ticks() -> u64 {
    #[cfg(target_arch = "aarch64")]
    return aarch64::ticks();
    #[cfg(target_arch = "x86_64")]
    return x86_64::ticks();
 }
 /// Acquire the tick frequency reported by the platform.
 fn arch_frequency() -> TickFrequency {
    #[cfg(target_arch = "aarch64")]
    return aarch64::frequency();
    #[cfg(target_arch = "x86_64")]
    return x86_64::frequency();
 }
 /// Platform timer that allows measurement of the elapsed time.
 #[derive(Clone, Copy, Debug, PartialEq, Eq)]
 pub struct PlatformTimer {
    /// The start tick value.
    start: u64,
    /// The tick frequency of the platform.
    frequency: TickFrequency,
 }
 impl PlatformTimer {
    /// Start a platform timer at the current instant.
    pub fn start() -> Self {
        Self {
            start: arch_ticks(),
            frequency: arch_frequency(),
        }
    }
    /// Measure the elapsed duration since the hardware started ticking upwards.
    pub fn elapsed_since_lifetime(&self) -> Duration {
        self.frequency.duration(arch_ticks())
    }
    /// Measure the elapsed duration since the timer was started.
    pub fn elapsed_since_start(&self) -> Duration {
        let duration = arch_ticks() - self.start;
        self.frequency.duration(duration)
    }
 }
--- a/src/platform/timer/aarch64.rs
+++ b/src/platform/timer/aarch64.rs
@@ -0,0 +1,33 @@
 use crate::platform::timer::TickFrequency;
 use std::arch::asm;
 /// Reads the cntvct_el0 counter and returns the value.
 pub fn ticks() -> u64 {
    let counter: u64;
    unsafe {
        asm!("mrs x0, cntvct_el0", out("x0") counter);
    }
    counter
 }
 /// We can use the actual ticks value as our start value.
 pub fn start() -> u64 {
    ticks()
 }
 /// We can use the actual ticks value as our stop value.
 pub fn stop() -> u64 {
    ticks()
 }
 /// Our frequency is provided by cntfrq_el0 on the platform.
 pub fn frequency() -> TickFrequency {
    let frequency: u64;
    unsafe {
        asm!(
            "mrs x0, cntfrq_el0",
            out("x0") frequency
        );
    }
    TickFrequency::Hardware(frequency)
 }
--- a/src/platform/timer/x86_64.rs
+++ b/src/platform/timer/x86_64.rs
@@ -0,0 +1,66 @@
 use crate::platform::timer::TickFrequency;
 use core::arch::asm;
 use std::time::Duration;
 /// We will measure the frequency of the timer based on 1000 microseconds.
 /// This will result in a call to BS->Stall(1000) in the end.
 const MEASURE_FREQUENCY_DURATION: Duration = Duration::from_micros(1000);
 /// Read the number of ticks from the platform timer.
 pub fn ticks() -> u64 {
    let mut eax: u32;
    let mut edx: u32;
    unsafe {
        asm!("rdtsc", out("eax") eax, out("edx") edx);
    }
    (edx as u64) << 32 | eax as u64
 }
 /// Read the starting number of ticks from the platform timer.
 pub fn start() -> u64 {
    let rax: u64;
    unsafe {
        asm!(
            "mfence",
            "lfence",
            "rdtsc",
            "shl rdx, 32",
            "or rax, rdx",
            out("rax") rax
        );
    }
    rax
 }
 /// Read the ending number of ticks from the platform timer.
 pub fn stop() -> u64 {
    let rax: u64;
    unsafe {
        asm!(
        "rdtsc",
        "lfence",
        "shl rdx, 32",
        "or rax, rdx",
        out("rax") rax
        );
    }
    rax
 }
 /// Measure the frequency of the platform timer.
 fn measure_frequency(duration: &Duration) -> u64 {
    let start = start();
    uefi::boot::stall(*duration);
    let stop = stop();
    let elapsed = (stop - start) as f64;
    (elapsed / duration.as_secs_f64()) as u64
 }
 /// Acquire the platform timer frequency.
 /// On x86_64, this is slightly expensive, so it should be done once.
 pub fn frequency() -> TickFrequency {
    let frequency = measure_frequency(&MEASURE_FREQUENCY_DURATION);
    TickFrequency::Measured(frequency, MEASURE_FREQUENCY_DURATION)
 }
--- a/src/utils.rs
+++ b/src/utils.rs
@@ -4,7 +4,9 @@ use uefi::fs::{FileSystem, Path};
 use uefi::proto::device_path::text::{AllowShortcuts, DevicePathFromText, DisplayOnly};
 use uefi::proto::device_path::{DevicePath, PoolDevicePath};
 use uefi::proto::media::fs::SimpleFileSystem;
-use uefi::{CString16, Handle};
+use uefi::proto::media::partition::PartitionInfo;
 use uefi::{CString16, Guid, Handle};
 use uefi_raw::Status;
 /// Support code for the EFI framebuffer.
 pub mod framebuffer;
@@ -181,3 +183,49 @@ pub fn combine_options<T: AsRef<str>>(options: impl Iterator<Item = T>) -> Strin
 pub fn unique_hash(input: &str) -> String {
    sha256::digest(input.as_bytes())
 }
 /// Represents the type of partition GUID that can be retrieved.
 #[derive(PartialEq, Eq)]
 pub enum PartitionGuidForm {
    Partition,
    PartitionType,
 }
 /// Retrieve the partition / partition type GUID of the device root `path`.
 /// This only works on GPT partitions. If the root is not a GPT partition, None is returned.
 pub fn partition_guid(path: &DevicePath, form: PartitionGuidForm) -> Result<Option<Guid>> {
    // Clone the path so we can pass it to the UEFI stack.
    let path = path.to_boxed();
    let result = uefi::boot::locate_device_path::<PartitionInfo>(&mut &*path);
    let handle = match result {
        Ok(handle) => Ok(Some(handle)),
        Err(error) => {
            // If the error is NOT_FOUND or UNSUPPORTED, we can return None.
            // These are non-fatal errors.
            if error.status() == Status::NOT_FOUND || error.status() == Status::UNSUPPORTED {
                Ok(None)
            } else {
                Err(error)
            }
        }
    }
    .context("unable to locate device path")?;
    // If we have the handle, we can try to open the partition info protocol.
    if let Some(handle) = handle {
        // Open the partition info protocol.
        let partition_info = uefi::boot::open_protocol_exclusive::<PartitionInfo>(handle)
            .context("unable to open partition info protocol")?;
        // Find the unique partition GUID.
        // If this is not a GPT partition, this will produce None.
        Ok(partition_info
            .gpt_partition_entry()
            .map(|entry| match form {
                // Match the form of the partition GUID.
                PartitionGuidForm::Partition => entry.unique_partition_guid,
                PartitionGuidForm::PartitionType => entry.partition_type_guid.0,
            }))
    } else {
        Ok(None)
    }
 }
		`@@ -0,0 +1,2 @@`
							`/// Implements support for the bootloader interface specification.`
							`pub mod bootloader_interface;`
		`@@ -0,0 +1,2 @@`
							`/// timer: Platform timer support.`
							`pub mod timer;`