#[cfg(feature = "alloc")] use core::{slice, iter}; use core::{str, char, cmp, num}; use io::prelude::*; use io; use io::{ErrorKind, SeekFrom}; use fs::{FileSystem, DiskSlice, ReadWriteSeek}; use file::File; use dir_entry::{DirEntry, DirEntryData, DirFileEntryData, DirLfnEntryData, FileAttributes, ShortName, DIR_ENTRY_SIZE}; #[cfg(feature = "alloc")] use dir_entry::{LFN_PART_LEN, LFN_ENTRY_LAST_FLAG}; #[cfg(all(not(feature = "std"), feature = "alloc"))] use alloc::Vec; pub(crate) enum DirRawStream<'a, T: ReadWriteSeek + 'a> { File(File<'a, T>), Root(DiskSlice<'a, T>), } impl <'a, T: ReadWriteSeek> DirRawStream<'a, T> { fn abs_pos(&self) -> Option { match self { &DirRawStream::File(ref file) => file.abs_pos(), &DirRawStream::Root(ref slice) => Some(slice.abs_pos()), } } fn first_cluster(&self) -> Option { match self { &DirRawStream::File(ref file) => file.first_cluster(), &DirRawStream::Root(_) => None, } } } // Note: derive cannot be used because of invalid bounds. See: https://github.com/rust-lang/rust/issues/26925 impl <'a, T: ReadWriteSeek> Clone for DirRawStream<'a, T> { fn clone(&self) -> Self { match self { &DirRawStream::File(ref file) => DirRawStream::File(file.clone()), &DirRawStream::Root(ref raw) => DirRawStream::Root(raw.clone()), } } } impl <'a, T: ReadWriteSeek> Read for DirRawStream<'a, T> { fn read(&mut self, buf: &mut [u8]) -> io::Result { match self { &mut DirRawStream::File(ref mut file) => file.read(buf), &mut DirRawStream::Root(ref mut raw) => raw.read(buf), } } } impl <'a, T: ReadWriteSeek> Write for DirRawStream<'a, T> { fn write(&mut self, buf: &[u8]) -> io::Result { match self { &mut DirRawStream::File(ref mut file) => file.write(buf), &mut DirRawStream::Root(ref mut raw) => raw.write(buf), } } fn flush(&mut self) -> io::Result<()> { match self { &mut DirRawStream::File(ref mut file) => file.flush(), &mut DirRawStream::Root(ref mut raw) => raw.flush(), } } } impl <'a, T: ReadWriteSeek> Seek for DirRawStream<'a, T> { fn seek(&mut self, pos: SeekFrom) -> io::Result { match self { &mut DirRawStream::File(ref mut file) => file.seek(pos), &mut DirRawStream::Root(ref mut raw) => raw.seek(pos), } } } fn split_path<'c>(path: &'c str) -> (&'c str, Option<&'c str>) { // remove trailing slash and split into 2 components - top-most parent and rest let mut path_split = path.trim_matches('/').splitn(2, "/"); let comp = path_split.next().unwrap(); // SAFE: splitn always returns at least one element let rest_opt = path_split.next(); (comp, rest_opt) } enum DirEntryOrShortName<'a, T: ReadWriteSeek + 'a> { DirEntry(DirEntry<'a, T>), ShortName([u8; 11]), } /// A FAT filesystem directory. /// /// This struct is created by the `open_dir` or `create_dir` methods on `Dir`. /// The root directory is returned by the `root_dir` method on `FileSystem`. pub struct Dir<'a, T: ReadWriteSeek + 'a> { stream: DirRawStream<'a, T>, fs: &'a FileSystem, } impl <'a, T: ReadWriteSeek + 'a> Dir<'a, T> { pub(crate) fn new(stream: DirRawStream<'a, T>, fs: &'a FileSystem) -> Self { Dir { stream, fs } } /// Creates directory entries iterator. pub fn iter(&self) -> DirIter<'a, T> { self.stream.clone(); DirIter { stream: self.stream.clone(), fs: self.fs.clone(), err: false, } } fn find_entry(&self, name: &str, is_dir: Option, mut short_name_gen: Option<&mut ShortNameGenerator>) -> io::Result> { for r in self.iter() { let e = r?; // compare name ignoring case if e.eq_name(name) { // check if file or directory is expected if is_dir.is_some() && Some(e.is_dir()) != is_dir { let error_msg = if e.is_dir() { "Is a directory" } else { "Not a directory" }; return Err(io::Error::new(ErrorKind::Other, error_msg)); } return Ok(e); } // update short name generator state if let Some(ref mut gen) = short_name_gen { gen.add_existing(e.raw_short_name()); } } Err(io::Error::new(ErrorKind::NotFound, "No such file or directory")) } fn check_for_existence(&self, name: &str, is_dir: Option) -> io::Result> { let mut short_name_gen = ShortNameGenerator::new(name); loop { let r = self.find_entry(name, is_dir, Some(&mut short_name_gen)); match r { Err(ref err) if err.kind() == ErrorKind::NotFound => {}, // other error Err(err) => return Err(err), // directory already exists - return it Ok(e) => return Ok(DirEntryOrShortName::DirEntry(e)), }; if let Ok(name) = short_name_gen.generate() { return Ok(DirEntryOrShortName::ShortName(name)); } short_name_gen.next_iteration(); } } /// Opens existing subdirectory. /// /// `path` is a '/' separated directory path relative to self directory. pub fn open_dir(&self, path: &str) -> io::Result { let (name, rest_opt) = split_path(path); let e = self.find_entry(name, Some(true), None)?; match rest_opt { Some(rest) => e.to_dir().open_dir(rest), None => Ok(e.to_dir()), } } /// Opens existing file. /// /// `path` is a '/' separated file path relative to self directory. pub fn open_file(&self, path: &str) -> io::Result> { // traverse path let (name, rest_opt) = split_path(path); if let Some(rest) = rest_opt { let e = self.find_entry(name, Some(true), None)?; return e.to_dir().open_file(rest); } // convert entry to a file let e = self.find_entry(name, Some(false), None)?; Ok(e.to_file()) } /// Creates new or opens existing file=. /// /// `path` is a '/' separated file path relative to self directory. /// File is never truncated when opening. It can be achieved by calling `File::truncate` method after opening. pub fn create_file(&self, path: &str) -> io::Result> { // traverse path let (name, rest_opt) = split_path(path); if let Some(rest) = rest_opt { return self.find_entry(name, Some(true), None)?.to_dir().create_file(rest); } // this is final filename in the path let r = self.check_for_existence(name, Some(false))?; match r { // file does not exist - create it DirEntryOrShortName::ShortName(short_name) => { let sfn_entry = self.create_sfn_entry(short_name, FileAttributes::from_bits_truncate(0), None); Ok(self.write_entry(name, sfn_entry)?.to_file()) }, // file already exists - return it DirEntryOrShortName::DirEntry(e) => Ok(e.to_file()), } } /// Creates new directory or opens existing. /// /// `path` is a '/' separated path relative to self directory. pub fn create_dir(&self, path: &str) -> io::Result { // traverse path let (name, rest_opt) = split_path(path); if let Some(rest) = rest_opt { return self.find_entry(name, Some(true), None)?.to_dir().create_dir(rest); } // this is final filename in the path let r = self.check_for_existence(name, Some(true))?; match r { // directory does not exist - create it DirEntryOrShortName::ShortName(short_name) => { // alloc cluster for directory data let cluster = self.fs.alloc_cluster(None)?; // create entry in parent directory let sfn_entry = self.create_sfn_entry(short_name, FileAttributes::DIRECTORY, Some(cluster)); let entry = self.write_entry(name, sfn_entry)?; let mut dir = entry.to_dir(); // create special entries "." and ".." let dot_sfn = ShortNameGenerator::new(".").generate().unwrap(); let sfn_entry = self.create_sfn_entry(dot_sfn, FileAttributes::DIRECTORY, entry.first_cluster()); dir.write_entry(".", sfn_entry)?; let dotdot_sfn = ShortNameGenerator::new("..").generate().unwrap(); let sfn_entry = self.create_sfn_entry(dotdot_sfn, FileAttributes::DIRECTORY, self.stream.first_cluster()); dir.write_entry("..", sfn_entry)?; Ok(dir) }, // directory already exists - return it DirEntryOrShortName::DirEntry(e) => Ok(e.to_dir()), } } fn is_empty(&self) -> io::Result { // check if directory contains no files for r in self.iter() { let e = r?; let name = e.short_file_name_as_bytes(); // ignore special entries "." and ".." if name != ".".as_bytes() && name != "..".as_bytes() { return Ok(false); } } Ok(true) } /// Removes existing file or directory. /// /// `path` is a '/' separated file path relative to self directory. /// Make sure there is no reference to this file (no File instance) or filesystem corruption /// can happen. pub fn remove(&self, path: &str) -> io::Result<()> { // traverse path let (name, rest_opt) = split_path(path); if let Some(rest) = rest_opt { let e = self.find_entry(name, Some(true), None)?; return e.to_dir().remove(rest); } trace!("removing {}", path); // in case of directory check if it is empty let e = self.find_entry(name, None, None)?; if e.is_dir() && !e.to_dir().is_empty()? { return Err(io::Error::new(ErrorKind::Other, "Directory not empty")); } // free data if let Some(n) = e.first_cluster() { self.fs.free_cluster_chain(n)?; } // free long and short name entries let mut stream = self.stream.clone(); stream.seek(SeekFrom::Start(e.offset_range.0 as u64))?; let num = (e.offset_range.1 - e.offset_range.0) as usize / DIR_ENTRY_SIZE as usize; for _ in 0..num { let mut data = DirEntryData::deserialize(&mut stream)?; trace!("removing dir entry {:?}", data); data.set_free(); stream.seek(SeekFrom::Current(-(DIR_ENTRY_SIZE as i64)))?; data.serialize(&mut stream)?; } Ok(()) } /// Renames or moves existing file or directory. /// /// `src_path` is a '/' separated source file path relative to self directory. /// `dst_path` is a '/' separated destination file path relative to `dst_dir`. /// `dst_dir` can be set to self directory if rename operation without moving is needed. /// Make sure there is no reference to this file (no File instance) or filesystem corruption /// can happen. pub fn rename(&self, src_path: &str, dst_dir: &Dir, dst_path: &str) -> io::Result<()> { // traverse source path let (name, rest_opt) = split_path(src_path); if let Some(rest) = rest_opt { let e = self.find_entry(name, Some(true), None)?; return e.to_dir().rename(rest, dst_dir, dst_path); } // traverse destination path let (name, rest_opt) = split_path(dst_path); if let Some(rest) = rest_opt { let e = dst_dir.find_entry(name, Some(true), None)?; return self.rename(src_path, &mut e.to_dir(), rest); } // move/rename file self.rename_internal(src_path, dst_dir, dst_path) } fn rename_internal(&self, src_name: &str, dst_dir: &Dir, dst_name: &str) -> io::Result<()> { trace!("moving {} to {}", src_name, dst_name); // find existing file let e = self.find_entry(src_name, None, None)?; // check if destionation filename is unused let r = dst_dir.check_for_existence(dst_name, None)?; let short_name = match r { DirEntryOrShortName::DirEntry(ref dst_e) => { // check if source and destination entry is the same if e.is_same_entry(dst_e) { return Ok(()); } return Err(io::Error::new(ErrorKind::AlreadyExists, "Destination file already exists")); }, DirEntryOrShortName::ShortName(short_name) => short_name, }; // free long and short name entries let mut stream = self.stream.clone(); stream.seek(SeekFrom::Start(e.offset_range.0 as u64))?; let num = (e.offset_range.1 - e.offset_range.0) as usize / DIR_ENTRY_SIZE as usize; for _ in 0..num { let mut data = DirEntryData::deserialize(&mut stream)?; trace!("removing LFN entry {:?}", data); data.set_free(); stream.seek(SeekFrom::Current(-(DIR_ENTRY_SIZE as i64)))?; data.serialize(&mut stream)?; } // save new directory entry let sfn_entry = e.data.renamed(short_name); dst_dir.write_entry(dst_name, sfn_entry)?; Ok(()) } fn find_free_entries(&self, num_entries: usize) -> io::Result> { let mut stream = self.stream.clone(); let mut first_free = 0; let mut num_free = 0; let mut i = 0; loop { let raw_entry = DirEntryData::deserialize(&mut stream)?; if raw_entry.is_end() { // first unused entry - all remaining space can be used if num_free == 0 { first_free = i; } stream.seek(io::SeekFrom::Start(first_free as u64 * DIR_ENTRY_SIZE))?; return Ok(stream); } else if raw_entry.is_free() { // free entry - calculate number of free entries in a row if num_free == 0 { first_free = i; } num_free += 1; if num_free == num_entries { // enough space for new file stream.seek(io::SeekFrom::Start(first_free as u64 * DIR_ENTRY_SIZE))?; return Ok(stream); } } else { // used entry - start counting from 0 num_free = 0; } i += 1; } } #[cfg(feature = "alloc")] fn create_lfn_entries(&self, name: &str, short_name: &[u8]) -> io::Result<(DirRawStream<'a, T>, u64)> { // get short name checksum let lfn_chsum = lfn_checksum(&short_name); // convert long name to UTF-16 let lfn_utf16 = name.encode_utf16().collect::>(); let lfn_iter = LfnEntriesGenerator::new(&lfn_utf16, lfn_chsum); // find space for new entries let num_entries = lfn_iter.len() + 1; // multiple lfn entries + one file entry let mut stream = self.find_free_entries(num_entries)?; let start_pos = stream.seek(io::SeekFrom::Current(0))?; // write LFN entries first for lfn_entry in lfn_iter { lfn_entry.serialize(&mut stream)?; } Ok((stream, start_pos)) } #[cfg(not(feature = "alloc"))] fn create_lfn_entries(&self, _name: &str, _short_name: &[u8]) -> io::Result<(DirRawStream<'a, T>, u64)> { let mut stream = self.find_free_entries(1)?; let start_pos = stream.seek(io::SeekFrom::Current(0))?; Ok((stream, start_pos)) } fn create_sfn_entry(&self, short_name: [u8; 11], attrs: FileAttributes, first_cluster: Option) -> DirFileEntryData { let mut raw_entry = DirFileEntryData::new(short_name, attrs); raw_entry.set_first_cluster(first_cluster, self.fs.fat_type()); raw_entry.reset_created(); raw_entry.reset_accessed(); raw_entry.reset_modified(); raw_entry } fn write_entry(&self, name: &str, raw_entry: DirFileEntryData) -> io::Result> { trace!("write_entry {}", name); // check if name doesn't contain unsupported characters validate_long_name(name)?; // generate long entries let (mut stream, start_pos) = self.create_lfn_entries(&name, raw_entry.name())?; // write short name entry raw_entry.serialize(&mut stream)?; let end_pos = stream.seek(io::SeekFrom::Current(0))?; let abs_pos = stream.abs_pos().map(|p| p - DIR_ENTRY_SIZE); // return new logical entry descriptor let short_name = ShortName::new(raw_entry.name()); return Ok(DirEntry { data: raw_entry, short_name, #[cfg(feature = "alloc")] lfn: Vec::new(), fs: self.fs, entry_pos: abs_pos.unwrap(), // SAFE: abs_pos is absent only for empty file offset_range: (start_pos, end_pos), }); } } // Note: derive cannot be used because of invalid bounds. See: https://github.com/rust-lang/rust/issues/26925 impl <'a, T: ReadWriteSeek> Clone for Dir<'a, T> { fn clone(&self) -> Self { Self { stream: self.stream.clone(), fs: self.fs, } } } /// An iterator over the directory entries. /// /// This struct is created by the `iter` method on `Dir`. pub struct DirIter<'a, T: ReadWriteSeek + 'a> { stream: DirRawStream<'a, T>, fs: &'a FileSystem, err: bool, } impl <'a, T: ReadWriteSeek> DirIter<'a, T> { fn read_dir_entry(&mut self) -> io::Result>> { #[cfg(feature = "alloc")] let mut lfn_buf = LongNameBuilder::new(); let mut offset = self.stream.seek(SeekFrom::Current(0))?; let mut begin_offset = offset; loop { let raw_entry = DirEntryData::deserialize(&mut self.stream)?; offset += DIR_ENTRY_SIZE; match raw_entry { DirEntryData::File(data) => { // Check if this is end of dif if data.is_end() { return Ok(None); } // Check if this is deleted or volume ID entry if data.is_free() || data.is_volume() { #[cfg(feature = "alloc")] lfn_buf.clear(); begin_offset = offset; continue; } // Get entry position on volume let abs_pos = self.stream.abs_pos().map(|p| p - DIR_ENTRY_SIZE); // Check if LFN checksum is valid #[cfg(feature = "alloc")] lfn_buf.validate_chksum(data.name()); // Return directory entry let short_name = ShortName::new(data.name()); return Ok(Some(DirEntry { data, short_name, #[cfg(feature = "alloc")] lfn: lfn_buf.to_vec(), fs: self.fs, entry_pos: abs_pos.unwrap(), // SAFE: abs_pos is empty only for empty file offset_range: (begin_offset, offset), })); }, DirEntryData::Lfn(data) => { // Check if this is deleted entry if data.is_free() { #[cfg(feature = "alloc")] lfn_buf.clear(); begin_offset = offset; continue; } // Append to LFN buffer #[cfg(feature = "alloc")] lfn_buf.process(&data); } } } } } // Note: derive cannot be used because of invalid bounds. See: https://github.com/rust-lang/rust/issues/26925 impl <'a, T: ReadWriteSeek> Clone for DirIter<'a, T> { fn clone(&self) -> Self { Self { stream: self.stream.clone(), fs: self.fs, err: self.err, } } } impl <'a, T: ReadWriteSeek> Iterator for DirIter<'a, T> { type Item = io::Result>; fn next(&mut self) -> Option { if self.err { return None; } let r = self.read_dir_entry(); match r { Ok(Some(e)) => Some(Ok(e)), Ok(None) => None, Err(err) => { self.err = true; Some(Err(err)) }, } } } fn validate_long_name(name: &str) -> io::Result<()> { // check if length is valid if name.len() == 0 { return Err(io::Error::new(ErrorKind::Other, "File name is empty")); } if name.len() > 255 { return Err(io::Error::new(ErrorKind::Other, "File name too long")); } // check if there are only valid characters for c in name.chars() { match c { 'a'...'z' | 'A'...'Z' | '0'...'9' | '\u{80}'...'\u{FFFF}' | '$' | '%' | '\'' | '-' | '_' | '@' | '~' | '`' | '!' | '(' | ')' | '{' | '}' | '.' | ' ' | '+' | ',' | ';' | '=' | '[' | ']' => {}, _ => return Err(io::Error::new(ErrorKind::Other, "File name contains unsupported characters")), } } Ok(()) } #[cfg(feature = "alloc")] fn lfn_checksum(short_name: &[u8]) -> u8 { let mut chksum = num::Wrapping(0u8); for i in 0..11 { chksum = (chksum << 7) + (chksum >> 1) + num::Wrapping(short_name[i]); } chksum.0 } #[cfg(feature = "alloc")] struct LongNameBuilder { buf: Vec, chksum: u8, index: u8, } #[cfg(feature = "alloc")] impl LongNameBuilder { fn new() -> Self { LongNameBuilder { buf: Vec::::new(), chksum: 0, index: 0, } } fn clear(&mut self) { self.buf.clear(); self.index = 0; } fn to_vec(mut self) -> Vec { if self.index == 1 { self.truncate(); self.buf } else { warn!("unfinished LFN sequence {}", self.index); Vec::::new() } } fn truncate(&mut self) { // Truncate 0 and 0xFFFF characters from LFN buffer let mut lfn_len = self.buf.len(); while lfn_len > 0 { match self.buf[lfn_len-1] { 0xFFFF | 0 => lfn_len -= 1, _ => break, } } self.buf.truncate(lfn_len); } fn process(&mut self, data: &DirLfnEntryData) { let is_last = (data.order() & LFN_ENTRY_LAST_FLAG) != 0; let index = data.order() & 0x1F; if index == 0 { // Corrupted entry warn!("currupted lfn entry! {:x}", data.order()); self.clear(); return; } if is_last { // last entry is actually first entry in stream self.index = index; self.chksum = data.checksum(); self.buf.resize(index as usize * LFN_PART_LEN, 0); } else if self.index == 0 || index != self.index - 1 || data.checksum() != self.chksum { // Corrupted entry warn!("currupted lfn entry! {:x} {:x} {:x} {:x}", data.order(), self.index, data.checksum(), self.chksum); self.clear(); return; } else { // Decrement LFN index only for non-last entries self.index -= 1; } let pos = LFN_PART_LEN * (index - 1) as usize; // copy name parts into LFN buffer data.copy_name_to_slice(&mut self.buf[pos..pos+13]); } fn validate_chksum(&mut self, short_name: &[u8]) { let chksum = lfn_checksum(short_name); if chksum != self.chksum { warn!("checksum mismatch {:x} {:x} {:?}", chksum, self.chksum, short_name); self.clear(); } } } #[cfg(feature = "alloc")] struct LfnEntriesGenerator<'a> { name_parts_iter: iter::Rev>, checksum: u8, index: usize, num: usize, ended: bool, } #[cfg(feature = "alloc")] impl<'a> LfnEntriesGenerator<'a> { fn new(name_utf16: &'a [u16], checksum: u8) -> Self { let num_entries = (name_utf16.len() + LFN_PART_LEN - 1) / LFN_PART_LEN; // create generator using reverse iterator over chunks - first chunk can be shorter LfnEntriesGenerator { checksum, name_parts_iter: name_utf16.chunks(LFN_PART_LEN).rev(), index: 0, num: num_entries, ended: false, } } } #[cfg(feature = "alloc")] impl<'a> Iterator for LfnEntriesGenerator<'a> { type Item = DirLfnEntryData; fn next(&mut self) -> Option { if self.ended { return None; } // get next part from reverse iterator match self.name_parts_iter.next() { Some(ref name_part) => { let lfn_index = self.num - self.index; let mut order = lfn_index as u8; if self.index == 0 { // this is last name part (written as first) order |= LFN_ENTRY_LAST_FLAG; } debug_assert!(order > 0); // name is padded with ' ' let mut lfn_part = [0xFFFFu16; LFN_PART_LEN]; lfn_part[..name_part.len()].copy_from_slice(&name_part); if name_part.len() < LFN_PART_LEN { // name is only zero-terminated if its length is not multiplicity of LFN_PART_LEN lfn_part[name_part.len()] = 0; } // create and return new LFN entry let mut lfn_entry = DirLfnEntryData::new(order, self.checksum); lfn_entry.copy_name_from_slice(&lfn_part); self.index += 1; Some(lfn_entry) }, None => { // end of name self.ended = true; None } } } fn size_hint(&self) -> (usize, Option) { self.name_parts_iter.size_hint() } } // name_parts_iter is ExactSizeIterator so size_hint returns one limit #[cfg(feature = "alloc")] impl<'a> ExactSizeIterator for LfnEntriesGenerator<'a> {} #[derive(Default, Debug, Clone)] struct ShortNameGenerator { chksum: u16, long_prefix_bitmap: u16, prefix_chksum_bitmap: u16, name_fits: bool, lossy_conv: bool, exact_match: bool, basename_len: u8, short_name: [u8; 11], } impl ShortNameGenerator { fn new(name: &str) -> Self { // padded by ' ' let mut short_name = [0x20u8; 11]; // find extension after last dot let (basename_len, name_fits, lossy_conv) = match name.rfind('.') { Some(index) => { // extension found - copy parts before and after dot let (basename_len, basename_fits, basename_lossy) = Self::copy_short_name_part(&mut short_name[0..8], &name[..index]); let (_, ext_fits, ext_lossy) = Self::copy_short_name_part(&mut short_name[8..11], &name[index+1..]); (basename_len, basename_fits && ext_fits, basename_lossy || ext_lossy) }, None => { // no extension - copy name and leave extension empty let (basename_len, basename_fits, basename_lossy) = Self::copy_short_name_part(&mut short_name[0..8], &name); (basename_len, basename_fits, basename_lossy) } }; let chksum = Self::checksum(name); Self { short_name, chksum, name_fits, lossy_conv, basename_len: basename_len as u8, ..Default::default() } } fn copy_short_name_part(dst: &mut [u8], src: &str) -> (usize, bool, bool) { let mut dst_pos = 0; let mut lossy_conv = false; for c in src.chars() { if dst_pos == dst.len() { // result buffer is full return (dst_pos, false, lossy_conv); } // Make sure character is allowed in 8.3 name let fixed_c = match c { // strip spaces and dots ' ' | '.' => { lossy_conv = true; continue; }, // copy allowed characters 'A'...'Z' | 'a'...'z' | '0'...'9' | '!' | '#' | '$' | '%' | '&' | '\'' | '(' | ')' | '-' | '@' | '^' | '_' | '`' | '{' | '}' | '~' => c, // replace disallowed characters by underscore _ => '_', }; // Update 'lossy conversion' flag lossy_conv = lossy_conv || (fixed_c != c); // short name is always uppercase let upper = fixed_c.to_ascii_uppercase(); dst[dst_pos] = upper as u8; // SAFE: upper is in range 0x20-0x7F dst_pos += 1; } (dst_pos, true, lossy_conv) } fn add_existing(&mut self, short_name: &[u8; 11]) { // check for exact match collision if short_name == &self.short_name { self.exact_match = true; } // check for long prefix form collision (TEXTFI~1.TXT) let prefix_len = cmp::min(self.basename_len, 6) as usize; let num_suffix = if short_name[prefix_len] as char == '~' { (short_name[prefix_len+1] as char).to_digit(10) } else { None }; let ext_matches = short_name[8..] == self.short_name[8..]; if short_name[..prefix_len] == self.short_name[..prefix_len] && num_suffix.is_some() && ext_matches { let num = num_suffix.unwrap(); // SAFE self.long_prefix_bitmap |= 1 << num; } // check for short prefix + checksum form collision (TE021F~1.TXT) let prefix_len = cmp::min(self.basename_len, 2) as usize; let num_suffix = if short_name[prefix_len+4] as char == '~' { (short_name[prefix_len+4+1] as char).to_digit(10) } else { None }; if short_name[..prefix_len] == self.short_name[..prefix_len] && num_suffix.is_some() && ext_matches { let chksum_res = str::from_utf8(&short_name[prefix_len..prefix_len+4]).map(|s| u16::from_str_radix(s, 16)); if chksum_res == Ok(Ok(self.chksum)) { let num = num_suffix.unwrap(); // SAFE self.prefix_chksum_bitmap |= 1 << num; } } } fn checksum(name: &str) -> u16 { // BSD checksum algorithm let mut chksum = num::Wrapping(0u16); for c in name.chars() { chksum = (chksum >> 1) + (chksum << 15) + num::Wrapping(c as u16); } chksum.0 } fn generate(&self) -> io::Result<[u8; 11]> { if !self.lossy_conv && self.name_fits && !self.exact_match { // If there was no lossy conversion and name fits into // 8.3 convention and there is no collision return it as is return Ok(self.short_name); } // Try using long 6-characters prefix for i in 1..5 { if self.long_prefix_bitmap & (1 << i) == 0 { return Ok(self.build_prefixed_name(i, false)); } } // Try prefix with checksum for i in 1..10 { if self.prefix_chksum_bitmap & (1 << i) == 0 { return Ok(self.build_prefixed_name(i, true)); } } // Too many collisions - fail Err(io::Error::new(ErrorKind::AlreadyExists, "short name already exists")) } fn next_iteration(&mut self) { // Try different checksum in next iteration self.chksum = (num::Wrapping(self.chksum) + num::Wrapping(1)).0; // Zero bitmaps self.long_prefix_bitmap = 0; self.prefix_chksum_bitmap = 0; } fn build_prefixed_name(&self, num: u32, with_chksum: bool) -> [u8; 11] { let mut buf = [0x20u8; 11]; let prefix_len = if with_chksum { let prefix_len = cmp::min(self.basename_len as usize, 2); buf[..prefix_len].copy_from_slice(&self.short_name[..prefix_len]); buf[prefix_len..prefix_len + 4].copy_from_slice(&Self::u16_to_u8_array(self.chksum)); prefix_len + 4 } else { let prefix_len = cmp::min(self.basename_len as usize, 6); buf[..prefix_len].copy_from_slice(&self.short_name[..prefix_len]); prefix_len }; buf[prefix_len] = '~' as u8; buf[prefix_len + 1] = char::from_digit(num, 10).unwrap() as u8; // SAFE buf[8..].copy_from_slice(&self.short_name[8..]); buf } fn u16_to_u8_array(x: u16) -> [u8;4] { let c1 = char::from_digit((x as u32 >> 12) & 0xF, 16).unwrap().to_ascii_uppercase() as u8; let c2 = char::from_digit((x as u32 >> 8) & 0xF, 16).unwrap().to_ascii_uppercase() as u8; let c3 = char::from_digit((x as u32 >> 4) & 0xF, 16).unwrap().to_ascii_uppercase() as u8; let c4 = char::from_digit((x as u32 >> 0) & 0xF, 16).unwrap().to_ascii_uppercase() as u8; return [c1, c2, c3, c4] } } #[cfg(test)] mod tests { use super::*; #[test] fn test_split_path() { assert_eq!(split_path("aaa/bbb/ccc"), ("aaa", Some("bbb/ccc"))); assert_eq!(split_path("aaa/bbb"), ("aaa", Some("bbb"))); assert_eq!(split_path("aaa"), ("aaa", None)); } #[test] fn test_generate_short_name() { assert_eq!(&ShortNameGenerator::new("Foo").generate().unwrap(), "FOO ".as_bytes()); assert_eq!(&ShortNameGenerator::new("Foo.b").generate().unwrap(), "FOO B ".as_bytes()); assert_eq!(&ShortNameGenerator::new("Foo.baR").generate().unwrap(), "FOO BAR".as_bytes()); assert_eq!(&ShortNameGenerator::new("Foo+1.baR").generate().unwrap(), "FOO_1~1 BAR".as_bytes()); assert_eq!(&ShortNameGenerator::new("ver +1.2.text").generate().unwrap(), "VER_12~1TEX".as_bytes()); assert_eq!(&ShortNameGenerator::new(".bashrc.swp").generate().unwrap(), "BASHRC~1SWP".as_bytes()); } #[test] fn test_short_name_checksum_overflow() { ShortNameGenerator::checksum("\u{FF5A}\u{FF5A}\u{FF5A}\u{FF5A}"); } #[test] fn test_lfn_checksum_overflow() { lfn_checksum(&[0xFFu8, 0xFFu8, 0xFFu8, 0xFFu8, 0xFFu8, 0xFFu8, 0xFFu8, 0xFFu8, 0xFFu8, 0xFFu8, 0xFFu8]); } #[test] fn test_generate_short_name_collisions_long() { let mut buf: [u8; 11]; let mut gen = ShortNameGenerator::new("TextFile.Mine.txt"); buf = gen.generate().unwrap(); assert_eq!(&buf, "TEXTFI~1TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "TEXTFI~2TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "TEXTFI~3TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "TEXTFI~4TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "TE527D~1TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "TE527D~2TXT".as_bytes()); for i in 3..10 { gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, format!("TE527D~{}TXT", i).as_bytes()); } gen.add_existing(&buf); assert!(gen.generate().is_err()); gen.next_iteration(); for _i in 0..4 { buf = gen.generate().unwrap(); gen.add_existing(&buf); } buf = gen.generate().unwrap(); assert_eq!(&buf, "TE527E~1TXT".as_bytes()); } #[test] fn test_generate_short_name_collisions_short() { let mut buf: [u8; 11]; let mut gen = ShortNameGenerator::new("x.txt"); buf = gen.generate().unwrap(); assert_eq!(&buf, "X TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "X~1 TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "X~2 TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "X~3 TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "X~4 TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "X40DA~1 TXT".as_bytes()); gen.add_existing(&buf); buf = gen.generate().unwrap(); assert_eq!(&buf, "X40DA~2 TXT".as_bytes()); } }