rust-fatfs/src/fs.rs

420 lines
14 KiB
Rust

use core::cell::RefCell;
use core::cmp;
use std::io::prelude::*;
use std::io::{Error, ErrorKind, SeekFrom};
use std::io;
use byteorder::{LittleEndian, ReadBytesExt};
use file::File;
use dir::{DirRawStream, Dir};
use dir_entry::DIR_ENTRY_SIZE;
use table::{ClusterIterator, alloc_cluster, read_fat_flags};
// FAT implementation based on:
// http://wiki.osdev.org/FAT
// https://www.win.tue.nl/~aeb/linux/fs/fat/fat-1.html
#[derive(Debug, Copy, Clone, PartialEq)]
pub enum FatType {
Fat12, Fat16, Fat32,
}
impl FatType {
fn from_clusters(total_clusters: u32) -> FatType {
if total_clusters < 4085 {
FatType::Fat12
} else if total_clusters < 65525 {
FatType::Fat16
} else {
FatType::Fat32
}
}
}
pub struct FsStatusFlags {
pub dirty: bool,
pub io_error: bool,
}
pub trait ReadSeek: Read + Seek {}
impl<T> ReadSeek for T where T: Read + Seek {}
pub trait ReadWriteSeek: Read + Write + Seek {}
impl<T> ReadWriteSeek for T where T: Read + Write + Seek {}
#[allow(dead_code)]
#[derive(Default, Debug, Clone)]
struct BiosParameterBlock {
bytes_per_sector: u16,
sectors_per_cluster: u8,
reserved_sectors: u16,
fats: u8,
root_entries: u16,
total_sectors_16: u16,
media: u8,
sectors_per_fat_16: u16,
sectors_per_track: u16,
heads: u16,
hidden_sectors: u32,
total_sectors_32: u32,
// Extended BIOS Parameter Block
sectors_per_fat_32: u32,
extended_flags: u16,
fs_version: u16,
root_dir_first_cluster: u32,
fs_info_sector: u16,
backup_boot_sector: u16,
reserved_0: [u8; 12],
drive_num: u8,
reserved_1: u8,
ext_sig: u8,
volume_id: u32,
volume_label: [u8; 11],
fs_type_label: [u8; 8],
}
impl BiosParameterBlock {
fn deserialize(rdr: &mut Read) -> io::Result<BiosParameterBlock> {
let mut bpb: BiosParameterBlock = Default::default();
bpb.bytes_per_sector = rdr.read_u16::<LittleEndian>()?;
bpb.sectors_per_cluster = rdr.read_u8()?;
bpb.reserved_sectors = rdr.read_u16::<LittleEndian>()?;
bpb.fats = rdr.read_u8()?;
bpb.root_entries = rdr.read_u16::<LittleEndian>()? ;
bpb.total_sectors_16 = rdr.read_u16::<LittleEndian>()?;
bpb.media = rdr.read_u8()?;
bpb.sectors_per_fat_16 = rdr.read_u16::<LittleEndian>()?;
bpb.sectors_per_track = rdr.read_u16::<LittleEndian>()?;
bpb.heads = rdr.read_u16::<LittleEndian>()?;
bpb.hidden_sectors = rdr.read_u32::<LittleEndian>()?;
bpb.total_sectors_32 = rdr.read_u32::<LittleEndian>()?;
// sanity checks
if bpb.bytes_per_sector < 512 {
return Err(Error::new(ErrorKind::Other, "invalid bytes_per_sector value in BPB"));
}
if bpb.sectors_per_cluster < 1 {
return Err(Error::new(ErrorKind::Other, "invalid sectors_per_cluster value in BPB"));
}
if bpb.reserved_sectors < 1 {
return Err(Error::new(ErrorKind::Other, "invalid reserved_sectors value in BPB"));
}
if bpb.fats == 0 {
return Err(Error::new(ErrorKind::Other, "invalid fats value in BPB"));
}
if bpb.sectors_per_fat_16 == 0 {
bpb.sectors_per_fat_32 = rdr.read_u32::<LittleEndian>()?;
bpb.extended_flags = rdr.read_u16::<LittleEndian>()?;
bpb.fs_version = rdr.read_u16::<LittleEndian>()?;
bpb.root_dir_first_cluster = rdr.read_u32::<LittleEndian>()?;
bpb.fs_info_sector = rdr.read_u16::<LittleEndian>()?;
bpb.backup_boot_sector = rdr.read_u16::<LittleEndian>()?;
rdr.read_exact(&mut bpb.reserved_0)?;
bpb.drive_num = rdr.read_u8()?;
bpb.reserved_1 = rdr.read_u8()?;
bpb.ext_sig = rdr.read_u8()?; // 0x29
bpb.volume_id = rdr.read_u32::<LittleEndian>()?;
rdr.read_exact(&mut bpb.volume_label)?;
rdr.read_exact(&mut bpb.fs_type_label)?;
} else {
bpb.drive_num = rdr.read_u8()?;
bpb.reserved_1 = rdr.read_u8()?;
bpb.ext_sig = rdr.read_u8()?; // 0x29
bpb.volume_id = rdr.read_u32::<LittleEndian>()?;
rdr.read_exact(&mut bpb.volume_label)?;
rdr.read_exact(&mut bpb.fs_type_label)?;
}
if bpb.ext_sig != 0x29 {
// fields after ext_sig are not used - clean them
bpb.volume_id = 0;
bpb.volume_label = [0; 11];
bpb.fs_type_label = [0; 8];
}
Ok(bpb)
}
fn mirroring_enabled(&self) -> bool {
self.extended_flags & 0x80 == 0
}
fn active_fat(&self) -> u16 {
self.extended_flags & 0x0F
}
fn status_flags(&self) -> FsStatusFlags {
FsStatusFlags {
dirty: self.reserved_1 & 1 != 0,
io_error: self.reserved_1 & 2 != 0,
}
}
}
#[allow(dead_code)]
struct BootRecord {
bootjmp: [u8; 3],
oem_name: [u8; 8],
bpb: BiosParameterBlock,
boot_code: [u8; 448],
boot_sig: [u8; 2],
}
impl BootRecord {
fn deserialize(rdr: &mut Read) -> io::Result<BootRecord> {
let mut boot: BootRecord = Default::default();
rdr.read_exact(&mut boot.bootjmp)?;
rdr.read_exact(&mut boot.oem_name)?;
boot.bpb = BiosParameterBlock::deserialize(rdr)?;
if boot.bpb.sectors_per_fat_16 == 0 {
rdr.read_exact(&mut boot.boot_code[0..420])?;
} else {
rdr.read_exact(&mut boot.boot_code[0..448])?;
}
rdr.read_exact(&mut boot.boot_sig)?;
Ok(boot)
}
}
impl Default for BootRecord {
fn default() -> BootRecord {
BootRecord {
bootjmp: Default::default(),
oem_name: Default::default(),
bpb: Default::default(),
boot_code: [0; 448],
boot_sig: Default::default(),
}
}
}
/// FAT filesystem options.
#[derive(Debug, Clone, Copy)]
pub struct FsOptions {
pub(crate) update_accessed_date: bool,
}
impl FsOptions {
pub fn new() -> Self {
FsOptions {
update_accessed_date: false,
}
}
/// If enabled library updates accessed date field in directory entry when reading
pub fn update_accessed_date(mut self, enabled: bool) -> Self {
self.update_accessed_date = enabled;
self
}
}
pub(crate) type FileSystemRef<'a, 'b> = &'a FileSystem<'b>;
/// FAT filesystem main struct.
pub struct FileSystem<'a> {
pub(crate) disk: RefCell<&'a mut ReadWriteSeek>,
pub(crate) options: FsOptions,
fat_type: FatType,
bpb: BiosParameterBlock,
first_data_sector: u32,
root_dir_sectors: u32,
}
impl <'a> FileSystem<'a> {
/// Creates new filesystem object instance.
///
/// Supplied disk parameter cannot be seeked. If there is a need to read a fragment of disk image (e.g. partition)
/// library user should provide a custom implementation of ReadWriteSeek trait.
///
/// Note: creating multiple filesystem objects with one underlying device/disk image can
/// cause filesystem corruption.
pub fn new<T: ReadWriteSeek>(disk: &'a mut T, options: FsOptions) -> io::Result<FileSystem<'a>> {
// Make sure given image is not seeked
debug_assert!(disk.seek(SeekFrom::Current(0))? == 0);
// Read boot sector
let bpb = {
let boot = BootRecord::deserialize(disk)?;
if boot.boot_sig != [0x55, 0xAA] {
return Err(Error::new(ErrorKind::Other, "invalid signature"));
}
boot.bpb
};
let total_sectors =
if bpb.total_sectors_16 == 0 { bpb.total_sectors_32 }
else { bpb.total_sectors_16 as u32 };
let sectors_per_fat =
if bpb.sectors_per_fat_16 == 0 { bpb.sectors_per_fat_32 }
else { bpb.sectors_per_fat_16 as u32 };
let root_dir_bytes = bpb.root_entries as u32 * DIR_ENTRY_SIZE as u32;
let root_dir_sectors = (root_dir_bytes + (bpb.bytes_per_sector as u32 - 1)) / bpb.bytes_per_sector as u32;
let first_data_sector = bpb.reserved_sectors as u32 + (bpb.fats as u32 * sectors_per_fat) + root_dir_sectors;
let fat_sectors = bpb.fats as u32 * sectors_per_fat;
let data_sectors = total_sectors - (bpb.reserved_sectors as u32 + fat_sectors + root_dir_sectors as u32);
let total_clusters = data_sectors / bpb.sectors_per_cluster as u32;
let fat_type = FatType::from_clusters(total_clusters);
Ok(FileSystem {
disk: RefCell::new(disk),
options,
fat_type,
bpb: bpb,
first_data_sector,
root_dir_sectors,
})
}
/// Returns type of used File Allocation Table (FAT).
pub fn fat_type(&self) -> FatType {
self.fat_type
}
/// Returns volume identifier read from BPB in Boot Sector.
pub fn volume_id(&self) -> u32 {
self.bpb.volume_id
}
/// Returns volume label from BPB in Boot Sector.
///
/// Note: File with VOLUME_ID attribute in root directory is ignored by this library.
/// Only label from BPB is used.
pub fn volume_label(&self) -> String {
String::from_utf8_lossy(&self.bpb.volume_label).trim_right().to_string()
}
/// Returns root directory object allowing futher penetration of filesystem structure.
pub fn root_dir<'b>(&'b self) -> Dir<'b, 'a> {
let root_rdr = {
match self.fat_type {
FatType::Fat12 | FatType::Fat16 => DirRawStream::Root(DiskSlice::from_sectors(
self.first_data_sector - self.root_dir_sectors, self.root_dir_sectors, 1, self)),
_ => DirRawStream::File(File::new(Some(self.bpb.root_dir_first_cluster), None, self)),
}
};
Dir::new(root_rdr, self)
}
pub(crate) fn offset_from_sector(&self, sector: u32) -> u64 {
(sector as u64) * self.bpb.bytes_per_sector as u64
}
pub(crate) fn sector_from_cluster(&self, cluster: u32) -> u32 {
((cluster - 2) * self.bpb.sectors_per_cluster as u32) + self.first_data_sector
}
pub(crate) fn cluster_size(&self) -> u32 {
self.bpb.sectors_per_cluster as u32 * self.bpb.bytes_per_sector as u32
}
pub(crate) fn offset_from_cluster(&self, cluser: u32) -> u64 {
self.offset_from_sector(self.sector_from_cluster(cluser))
}
fn fat_slice<'b>(&'b self) -> DiskSlice<'b, 'a> {
let sectors_per_fat =
if self.bpb.sectors_per_fat_16 == 0 { self.bpb.sectors_per_fat_32 }
else { self.bpb.sectors_per_fat_16 as u32 };
let mirroring_enabled = self.bpb.mirroring_enabled();
let (fat_first_sector, mirrors) = if mirroring_enabled {
(self.bpb.reserved_sectors as u32, self.bpb.fats)
} else {
let active_fat = self.bpb.active_fat() as u32;
let fat_first_sector = (self.bpb.reserved_sectors as u32) + active_fat * sectors_per_fat;
(fat_first_sector, 1)
};
DiskSlice::from_sectors(fat_first_sector, sectors_per_fat, mirrors, self)
}
pub(crate) fn cluster_iter<'b>(&'b self, cluster: u32) -> ClusterIterator<'b, 'a> {
let disk_slice = self.fat_slice();
ClusterIterator::new(disk_slice, self.fat_type, cluster)
}
pub(crate) fn alloc_cluster(&self, prev_cluster: Option<u32>) -> io::Result<u32> {
let mut disk_slice = self.fat_slice();
alloc_cluster(&mut disk_slice, self.fat_type, prev_cluster)
}
pub fn read_status_flags(&self) -> io::Result<FsStatusFlags> {
let bpb_status = self.bpb.status_flags();
let fat_status = read_fat_flags(&mut self.fat_slice(), self.fat_type)?;
Ok(FsStatusFlags {
dirty: bpb_status.dirty || fat_status.dirty,
io_error: bpb_status.io_error || fat_status.io_error,
})
}
}
#[derive(Clone)]
pub(crate) struct DiskSlice<'a, 'b: 'a> {
begin: u64,
size: u64,
offset: u64,
mirrors: u8,
fs: &'a FileSystem<'b>,
}
impl <'a, 'b> DiskSlice<'a, 'b> {
pub(crate) fn new(begin: u64, size: u64, mirrors: u8, fs: FileSystemRef<'a, 'b>) -> Self {
DiskSlice { begin, size, mirrors, fs, offset: 0 }
}
pub(crate) fn from_sectors(first_sector: u32, sector_count: u32, mirrors: u8, fs: FileSystemRef<'a, 'b>) -> Self {
let bytes_per_sector = fs.bpb.bytes_per_sector as u64;
Self::new(first_sector as u64 * bytes_per_sector, sector_count as u64 * bytes_per_sector, mirrors, fs)
}
pub(crate) fn abs_pos(&self) -> u64 {
self.begin + self.offset
}
}
impl <'a, 'b> Read for DiskSlice<'a, 'b> {
fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> {
let offset = self.begin + self.offset;
let read_size = cmp::min((self.size - self.offset) as usize, buf.len());
let mut disk = self.fs.disk.borrow_mut();
disk.seek(SeekFrom::Start(offset))?;
let size = disk.read(&mut buf[..read_size])?;
self.offset += size as u64;
Ok(size)
}
}
impl <'a, 'b> Write for DiskSlice<'a, 'b> {
fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
let offset = self.begin + self.offset;
let write_size = cmp::min((self.size - self.offset) as usize, buf.len());
for i in 0..self.mirrors {
let mut disk = self.fs.disk.borrow_mut();
disk.seek(SeekFrom::Start(offset + i as u64 * self.size))?;
disk.write_all(&buf[..write_size])?;
}
self.offset += write_size as u64;
Ok(write_size)
}
fn flush(&mut self) -> io::Result<()> {
let mut disk = self.fs.disk.borrow_mut();
disk.flush()
}
}
impl <'a, 'b> Seek for DiskSlice<'a, 'b> {
fn seek(&mut self, pos: SeekFrom) -> io::Result<u64> {
let new_offset = match pos {
SeekFrom::Current(x) => self.offset as i64 + x,
SeekFrom::Start(x) => x as i64,
SeekFrom::End(x) => self.size as i64 + x,
};
if new_offset < 0 || new_offset as u64 > self.size {
Err(io::Error::new(ErrorKind::InvalidInput, "invalid seek"))
} else {
self.offset = new_offset as u64;
Ok(self.offset)
}
}
}