crosvm/disk/src/gpt.rs

// Copyright 2021 The Chromium OS Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.

//! Functions for writing GUID Partition Tables for use in a composite disk image.

use std::convert::TryInto;
use std::io::{self, Write};
use std::num::TryFromIntError;

use crc32fast::Hasher;
use remain::sorted;
use thiserror::Error as ThisError;
use uuid::Uuid;

/// The size in bytes of a disk sector (also called a block).
pub const SECTOR_SIZE: u64 = 1 << 9;
/// The size in bytes on an MBR partition entry.
const MBR_PARTITION_ENTRY_SIZE: usize = 16;
/// The size in bytes of a GPT header.
pub const GPT_HEADER_SIZE: u32 = 92;
/// The number of partition entries in the GPT, which is the maximum number of partitions which are
/// supported.
pub const GPT_NUM_PARTITIONS: u32 = 128;
/// The size in bytes of a single GPT partition entry.
pub const GPT_PARTITION_ENTRY_SIZE: u32 = 128;
/// The size in bytes of everything before the first partition: i.e. the MBR, GPT header and GPT
/// partition entries.
pub const GPT_BEGINNING_SIZE: u64 = SECTOR_SIZE * 40;
/// The size in bytes of everything after the last partition: i.e. the GPT partition entries and GPT
/// footer.
pub const GPT_END_SIZE: u64 = SECTOR_SIZE * 33;

#[sorted]
#[derive(ThisError, Debug)]
pub enum Error {
    /// The disk size was invalid (too large).
    #[error("invalid disk size: {0}")]
    InvalidDiskSize(TryFromIntError),
    /// There was an error writing data to one of the image files.
    #[error("failed to write data: {0}")]
    WritingData(io::Error),
}

/// Write a protective MBR for a disk of the given total size (in bytes).
///
/// This should be written at the start of the disk, before the GPT header. It is one `SECTOR_SIZE`
/// long.
pub fn write_protective_mbr(file: &mut impl Write, disk_size: u64) -> Result<(), Error> {
    // Bootstrap code
    file.write_all(&[0; 446]).map_err(Error::WritingData)?;

    // Partition status
    file.write_all(&[0x00]).map_err(Error::WritingData)?;
    // Begin CHS
    file.write_all(&[0; 3]).map_err(Error::WritingData)?;
    // Partition type
    file.write_all(&[0xEE]).map_err(Error::WritingData)?;
    // End CHS
    file.write_all(&[0; 3]).map_err(Error::WritingData)?;
    let first_lba: u32 = 1;
    file.write_all(&first_lba.to_le_bytes())
        .map_err(Error::WritingData)?;
    let number_of_sectors: u32 = (disk_size / SECTOR_SIZE)
        .try_into()
        .map_err(Error::InvalidDiskSize)?;
    file.write_all(&number_of_sectors.to_le_bytes())
        .map_err(Error::WritingData)?;

    // Three more empty partitions
    file.write_all(&[0; MBR_PARTITION_ENTRY_SIZE * 3])
        .map_err(Error::WritingData)?;

    // Boot signature
    file.write_all(&[0x55, 0xAA]).map_err(Error::WritingData)?;

    Ok(())
}

#[derive(Clone, Debug, Default, Eq, PartialEq)]
struct GptHeader {
    signature: [u8; 8],
    revision: [u8; 4],
    header_size: u32,
    header_crc32: u32,
    current_lba: u64,
    backup_lba: u64,
    first_usable_lba: u64,
    last_usable_lba: u64,
    disk_guid: Uuid,
    partition_entries_lba: u64,
    num_partition_entries: u32,
    partition_entry_size: u32,
    partition_entries_crc32: u32,
}

impl GptHeader {
    fn write_bytes(&self, out: &mut impl Write) -> Result<(), Error> {
        out.write_all(&self.signature).map_err(Error::WritingData)?;
        out.write_all(&self.revision).map_err(Error::WritingData)?;
        out.write_all(&self.header_size.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.header_crc32.to_le_bytes())
            .map_err(Error::WritingData)?;
        // Reserved
        out.write_all(&[0; 4]).map_err(Error::WritingData)?;
        out.write_all(&self.current_lba.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.backup_lba.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.first_usable_lba.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.last_usable_lba.to_le_bytes())
            .map_err(Error::WritingData)?;

        // GUID is mixed-endian for some reason, so we can't just use `Uuid::as_bytes()`.
        write_guid(out, self.disk_guid).map_err(Error::WritingData)?;

        out.write_all(&self.partition_entries_lba.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.num_partition_entries.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.partition_entry_size.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.partition_entries_crc32.to_le_bytes())
            .map_err(Error::WritingData)?;
        Ok(())
    }
}

/// Write a GPT header for the disk.
///
/// It may either be a primary header (which should go at LBA 1) or a secondary header (which should
/// go at the end of the disk).
pub fn write_gpt_header(
    out: &mut impl Write,
    disk_guid: Uuid,
    partition_entries_crc32: u32,
    secondary_table_offset: u64,
    secondary: bool,
) -> Result<(), Error> {
    let primary_header_lba = 1;
    let secondary_header_lba = (secondary_table_offset + GPT_END_SIZE) / SECTOR_SIZE - 1;
    let mut gpt_header = GptHeader {
        signature: *b"EFI PART",
        revision: [0, 0, 1, 0],
        header_size: GPT_HEADER_SIZE,
        current_lba: if secondary {
            secondary_header_lba
        } else {
            primary_header_lba
        },
        backup_lba: if secondary {
            primary_header_lba
        } else {
            secondary_header_lba
        },
        first_usable_lba: GPT_BEGINNING_SIZE / SECTOR_SIZE,
        last_usable_lba: secondary_table_offset / SECTOR_SIZE - 1,
        disk_guid,
        partition_entries_lba: 2,
        num_partition_entries: GPT_NUM_PARTITIONS,
        partition_entry_size: GPT_PARTITION_ENTRY_SIZE,
        partition_entries_crc32,
        header_crc32: 0,
    };

    // Write once to a temporary buffer to calculate the CRC.
    let mut header_without_crc = [0u8; GPT_HEADER_SIZE as usize];
    gpt_header.write_bytes(&mut &mut header_without_crc[..])?;
    let mut hasher = Hasher::new();
    hasher.update(&header_without_crc);
    gpt_header.header_crc32 = hasher.finalize();

    gpt_header.write_bytes(out)?;

    Ok(())
}

/// A GPT entry for a particular partition.
#[derive(Clone, Debug, Eq, PartialEq)]
pub struct GptPartitionEntry {
    pub partition_type_guid: Uuid,
    pub unique_partition_guid: Uuid,
    pub first_lba: u64,
    pub last_lba: u64,
    pub attributes: u64,
    /// UTF-16LE
    pub partition_name: [u16; 36],
}

// This is implemented manually because `Default` isn't implemented in the standard library for
// arrays of more than 32 elements. If that gets implemented (now than const generics are in) then
// we can derive this instead.
impl Default for GptPartitionEntry {
    fn default() -> Self {
        Self {
            partition_type_guid: Default::default(),
            unique_partition_guid: Default::default(),
            first_lba: 0,
            last_lba: 0,
            attributes: 0,
            partition_name: [0; 36],
        }
    }
}

impl GptPartitionEntry {
    /// Write out the partition table entry. It will take
    /// `GPT_PARTITION_ENTRY_SIZE` bytes.
    pub fn write_bytes(&self, out: &mut impl Write) -> Result<(), Error> {
        write_guid(out, self.partition_type_guid).map_err(Error::WritingData)?;
        write_guid(out, self.unique_partition_guid).map_err(Error::WritingData)?;
        out.write_all(&self.first_lba.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.last_lba.to_le_bytes())
            .map_err(Error::WritingData)?;
        out.write_all(&self.attributes.to_le_bytes())
            .map_err(Error::WritingData)?;
        for code_unit in &self.partition_name {
            out.write_all(&code_unit.to_le_bytes())
                .map_err(Error::WritingData)?;
        }
        Ok(())
    }
}

/// Write a UUID in the mixed-endian format which GPT uses for GUIDs.
fn write_guid(out: &mut impl Write, guid: Uuid) -> Result<(), io::Error> {
    let guid_fields = guid.as_fields();
    out.write_all(&guid_fields.0.to_le_bytes())?;
    out.write_all(&guid_fields.1.to_le_bytes())?;
    out.write_all(&guid_fields.2.to_le_bytes())?;
    out.write_all(guid_fields.3)?;

    Ok(())
}

#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn protective_mbr_size() {
        let mut buffer = vec![];
        write_protective_mbr(&mut buffer, 1000 * SECTOR_SIZE).unwrap();

        assert_eq!(buffer.len(), SECTOR_SIZE as usize);
    }

    #[test]
    fn header_size() {
        let mut buffer = vec![];
        write_gpt_header(
            &mut buffer,
            Uuid::from_u128(0x12345678_1234_5678_abcd_12345678abcd),
            42,
            1000 * SECTOR_SIZE,
            false,
        )
        .unwrap();

        assert_eq!(buffer.len(), GPT_HEADER_SIZE as usize);
    }

    #[test]
    fn partition_entry_size() {
        let mut buffer = vec![];
        GptPartitionEntry::default()
            .write_bytes(&mut buffer)
            .unwrap();

        assert_eq!(buffer.len(), GPT_PARTITION_ENTRY_SIZE as usize);
    }
}
Add methods to create composite disk image. This can be used like: crosvm create_composite composite.img partiton1:partition1.img partition2:partition2.img BUG=b:190503456 TEST=cargo test Cq-Depend: chromium:2982777, chromium:3008399 Change-Id: I31a9afe1e5f1e2a850ce1f892122150bcf3441b4 Reviewed-on: https://chromium-review.googlesource.com/c/chromiumos/platform/crosvm/+/2972869 Tested-by: kokoro <noreply+kokoro@google.com> Reviewed-by: Keiichi Watanabe <keiichiw@chromium.org> Reviewed-by: Chirantan Ekbote <chirantan@chromium.org> Commit-Queue: Keiichi Watanabe <keiichiw@chromium.org> Auto-Submit: Andrew Walbran <qwandor@google.com> 2021-06-17 17:12:14 +00:00			`// Copyright 2021 The Chromium OS Authors. All rights reserved.`
			`// Use of this source code is governed by a BSD-style license that can be`
			`// found in the LICENSE file.`

			`//! Functions for writing GUID Partition Tables for use in a composite disk image.`

			`use std::convert::TryInto;`
			`use std::io::{self, Write};`
			`use std::num::TryFromIntError;`

			`use crc32fast::Hasher;`
			`use remain::sorted;`
			`use thiserror::Error as ThisError;`
			`use uuid::Uuid;`

			`/// The size in bytes of a disk sector (also called a block).`
			`pub const SECTOR_SIZE: u64 = 1 << 9;`
			`/// The size in bytes on an MBR partition entry.`
			`const MBR_PARTITION_ENTRY_SIZE: usize = 16;`
			`/// The size in bytes of a GPT header.`
			`pub const GPT_HEADER_SIZE: u32 = 92;`
			`/// The number of partition entries in the GPT, which is the maximum number of partitions which are`
			`/// supported.`
			`pub const GPT_NUM_PARTITIONS: u32 = 128;`
			`/// The size in bytes of a single GPT partition entry.`
			`pub const GPT_PARTITION_ENTRY_SIZE: u32 = 128;`
			`/// The size in bytes of everything before the first partition: i.e. the MBR, GPT header and GPT`
			`/// partition entries.`
			`pub const GPT_BEGINNING_SIZE: u64 = SECTOR_SIZE * 40;`
			`/// The size in bytes of everything after the last partition: i.e. the GPT partition entries and GPT`
			`/// footer.`
			`pub const GPT_END_SIZE: u64 = SECTOR_SIZE * 33;`

			`#[sorted]`
			`#[derive(ThisError, Debug)]`
			`pub enum Error {`
			`/// The disk size was invalid (too large).`
			`#[error("invalid disk size: {0}")]`
			`InvalidDiskSize(TryFromIntError),`
			`/// There was an error writing data to one of the image files.`
			`#[error("failed to write data: {0}")]`
			`WritingData(io::Error),`
			`}`

			`/// Write a protective MBR for a disk of the given total size (in bytes).`
			`///`
			/// This should be written at the start of the disk, before the GPT header. It is one `SECTOR_SIZE`
			`/// long.`
			`pub fn write_protective_mbr(file: &mut impl Write, disk_size: u64) -> Result<(), Error> {`
			`// Bootstrap code`
			`file.write_all(&[0; 446]).map_err(Error::WritingData)?;`

			`// Partition status`
			`file.write_all(&[0x00]).map_err(Error::WritingData)?;`
			`// Begin CHS`
			`file.write_all(&[0; 3]).map_err(Error::WritingData)?;`
			`// Partition type`
			`file.write_all(&[0xEE]).map_err(Error::WritingData)?;`
			`// End CHS`
			`file.write_all(&[0; 3]).map_err(Error::WritingData)?;`
			`let first_lba: u32 = 1;`
			`file.write_all(&first_lba.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`let number_of_sectors: u32 = (disk_size / SECTOR_SIZE)`
			`.try_into()`
			`.map_err(Error::InvalidDiskSize)?;`
			`file.write_all(&number_of_sectors.to_le_bytes())`
			`.map_err(Error::WritingData)?;`

			`// Three more empty partitions`
			`file.write_all(&[0; MBR_PARTITION_ENTRY_SIZE * 3])`
			`.map_err(Error::WritingData)?;`

			`// Boot signature`
			`file.write_all(&[0x55, 0xAA]).map_err(Error::WritingData)?;`

			`Ok(())`
			`}`

			`#[derive(Clone, Debug, Default, Eq, PartialEq)]`
			`struct GptHeader {`
			`signature: [u8; 8],`
			`revision: [u8; 4],`
			`header_size: u32,`
			`header_crc32: u32,`
			`current_lba: u64,`
			`backup_lba: u64,`
			`first_usable_lba: u64,`
			`last_usable_lba: u64,`
			`disk_guid: Uuid,`
			`partition_entries_lba: u64,`
			`num_partition_entries: u32,`
			`partition_entry_size: u32,`
			`partition_entries_crc32: u32,`
			`}`

			`impl GptHeader {`
			`fn write_bytes(&self, out: &mut impl Write) -> Result<(), Error> {`
			`out.write_all(&self.signature).map_err(Error::WritingData)?;`
			`out.write_all(&self.revision).map_err(Error::WritingData)?;`
			`out.write_all(&self.header_size.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.header_crc32.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`// Reserved`
			`out.write_all(&[0; 4]).map_err(Error::WritingData)?;`
			`out.write_all(&self.current_lba.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.backup_lba.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.first_usable_lba.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.last_usable_lba.to_le_bytes())`
			`.map_err(Error::WritingData)?;`

			// GUID is mixed-endian for some reason, so we can't just use `Uuid::as_bytes()`.
			`write_guid(out, self.disk_guid).map_err(Error::WritingData)?;`

			`out.write_all(&self.partition_entries_lba.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.num_partition_entries.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.partition_entry_size.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.partition_entries_crc32.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`Ok(())`
			`}`
			`}`

			`/// Write a GPT header for the disk.`
			`///`
			`/// It may either be a primary header (which should go at LBA 1) or a secondary header (which should`
			`/// go at the end of the disk).`
			`pub fn write_gpt_header(`
			`out: &mut impl Write,`
			`disk_guid: Uuid,`
			`partition_entries_crc32: u32,`
			`secondary_table_offset: u64,`
			`secondary: bool,`
			`) -> Result<(), Error> {`
			`let primary_header_lba = 1;`
			`let secondary_header_lba = (secondary_table_offset + GPT_END_SIZE) / SECTOR_SIZE - 1;`
			`let mut gpt_header = GptHeader {`
			`signature: *b"EFI PART",`
			`revision: [0, 0, 1, 0],`
			`header_size: GPT_HEADER_SIZE,`
			`current_lba: if secondary {`
			`secondary_header_lba`
			`} else {`
			`primary_header_lba`
			`},`
			`backup_lba: if secondary {`
			`primary_header_lba`
			`} else {`
			`secondary_header_lba`
			`},`
			`first_usable_lba: GPT_BEGINNING_SIZE / SECTOR_SIZE,`
			`last_usable_lba: secondary_table_offset / SECTOR_SIZE - 1,`
			`disk_guid,`
			`partition_entries_lba: 2,`
			`num_partition_entries: GPT_NUM_PARTITIONS,`
			`partition_entry_size: GPT_PARTITION_ENTRY_SIZE,`
			`partition_entries_crc32,`
			`header_crc32: 0,`
			`};`

			`// Write once to a temporary buffer to calculate the CRC.`
			`let mut header_without_crc = [0u8; GPT_HEADER_SIZE as usize];`
			`gpt_header.write_bytes(&mut &mut header_without_crc[..])?;`
			`let mut hasher = Hasher::new();`
			`hasher.update(&header_without_crc);`
			`gpt_header.header_crc32 = hasher.finalize();`

			`gpt_header.write_bytes(out)?;`

			`Ok(())`
			`}`

			`/// A GPT entry for a particular partition.`
			`#[derive(Clone, Debug, Eq, PartialEq)]`
			`pub struct GptPartitionEntry {`
			`pub partition_type_guid: Uuid,`
			`pub unique_partition_guid: Uuid,`
			`pub first_lba: u64,`
			`pub last_lba: u64,`
			`pub attributes: u64,`
			`/// UTF-16LE`
			`pub partition_name: [u16; 36],`
			`}`

			// This is implemented manually because `Default` isn't implemented in the standard library for
			`// arrays of more than 32 elements. If that gets implemented (now than const generics are in) then`
			`// we can derive this instead.`
			`impl Default for GptPartitionEntry {`
			`fn default() -> Self {`
			`Self {`
			`partition_type_guid: Default::default(),`
			`unique_partition_guid: Default::default(),`
			`first_lba: 0,`
			`last_lba: 0,`
			`attributes: 0,`
			`partition_name: [0; 36],`
			`}`
			`}`
			`}`

			`impl GptPartitionEntry {`
			`/// Write out the partition table entry. It will take`
			/// `GPT_PARTITION_ENTRY_SIZE` bytes.
			`pub fn write_bytes(&self, out: &mut impl Write) -> Result<(), Error> {`
			`write_guid(out, self.partition_type_guid).map_err(Error::WritingData)?;`
			`write_guid(out, self.unique_partition_guid).map_err(Error::WritingData)?;`
			`out.write_all(&self.first_lba.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.last_lba.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`out.write_all(&self.attributes.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`for code_unit in &self.partition_name {`
			`out.write_all(&code_unit.to_le_bytes())`
			`.map_err(Error::WritingData)?;`
			`}`
			`Ok(())`
			`}`
			`}`

			`/// Write a UUID in the mixed-endian format which GPT uses for GUIDs.`
			`fn write_guid(out: &mut impl Write, guid: Uuid) -> Result<(), io::Error> {`
			`let guid_fields = guid.as_fields();`
			`out.write_all(&guid_fields.0.to_le_bytes())?;`
			`out.write_all(&guid_fields.1.to_le_bytes())?;`
			`out.write_all(&guid_fields.2.to_le_bytes())?;`
			`out.write_all(guid_fields.3)?;`

			`Ok(())`
			`}`

			`#[cfg(test)]`
			`mod tests {`
			`use super::*;`

			`#[test]`
			`fn protective_mbr_size() {`
			`let mut buffer = vec![];`
			`write_protective_mbr(&mut buffer, 1000 * SECTOR_SIZE).unwrap();`

			`assert_eq!(buffer.len(), SECTOR_SIZE as usize);`
			`}`

			`#[test]`
			`fn header_size() {`
			`let mut buffer = vec![];`
			`write_gpt_header(`
			`&mut buffer,`
			`Uuid::from_u128(0x12345678_1234_5678_abcd_12345678abcd),`
			`42,`
			`1000 * SECTOR_SIZE,`
			`false,`
			`)`
			`.unwrap();`

			`assert_eq!(buffer.len(), GPT_HEADER_SIZE as usize);`
			`}`

			`#[test]`
			`fn partition_entry_size() {`
			`let mut buffer = vec![];`
			`GptPartitionEntry::default()`
			`.write_bytes(&mut buffer)`
			`.unwrap();`

			`assert_eq!(buffer.len(), GPT_PARTITION_ENTRY_SIZE as usize);`
			`}`
			`}`