mod counting_writer;
#[cfg(all(feature = "util", not(target_arch = "wasm32")))]
mod lazy_file_reader;
mod pack_info;
mod seq_reader;
mod source_reader;
mod unpack_info;
use std::{
cell::Cell,
io::{Read, Seek, Write},
rc::Rc,
sync::Arc,
};
#[cfg(not(target_arch = "wasm32"))]
use std::{fs::File, path::Path};
pub(crate) use counting_writer::CountingWriter;
use crc32fast::Hasher;
#[cfg(all(feature = "util", not(target_arch = "wasm32")))]
pub(crate) use self::lazy_file_reader::LazyFileReader;
pub(crate) use self::seq_reader::SeqReader;
pub use self::source_reader::SourceReader;
use self::{pack_info::PackInfo, unpack_info::UnpackInfo};
use crate::{
ArchiveEntry, AutoFinish, AutoFinisher, ByteWriter, Error,
archive::*,
bitset::{BitSet, write_bit_set},
encoder,
};
macro_rules! write_times {
($fn_name:tt, $nid:expr, $has_time:tt, $time:tt) => {
write_times!($fn_name, $nid, $has_time, $time, write_u64);
};
($fn_name:tt, $nid:expr, $has_time:tt, $time:tt, $write_fn:tt) => {
fn $fn_name<H: Write>(&self, header: &mut H) -> std::io::Result<()> {
let mut num = 0;
for entry in self.files.iter() {
if entry.$has_time {
num += 1;
}
}
if num > 0 {
header.write_u8($nid)?;
let mut temp: Vec<u8> = Vec::with_capacity(128);
let mut out = &mut temp;
if num != self.files.len() {
out.write_u8(0)?;
let mut times = BitSet::with_capacity(self.files.len());
for i in 0..self.files.len() {
if self.files[i].$has_time {
times.insert(i);
}
}
write_bit_set(&mut out, ×)?;
} else {
out.write_u8(1)?;
}
out.write_u8(0)?;
for file in self.files.iter() {
if file.$has_time {
out.$write_fn((file.$time).into())?;
}
}
out.flush()?;
write_u64(header, temp.len() as u64)?;
header.write_all(&temp)?;
}
Ok(())
}
};
}
type Result<T> = std::result::Result<T, Error>;
pub struct ArchiveWriter<W: Write> {
output: W,
files: Vec<ArchiveEntry>,
content_methods: Arc<Vec<EncoderConfiguration>>,
pack_info: PackInfo,
unpack_info: UnpackInfo,
encrypt_header: bool,
}
#[cfg(not(target_arch = "wasm32"))]
impl ArchiveWriter<File> {
pub fn create(path: impl AsRef<Path>) -> Result<Self> {
let file = File::create(path.as_ref())
.map_err(|e| Error::file_open(e, path.as_ref().to_string_lossy().to_string()))?;
Self::new(file)
}
}
impl<W: Write + Seek> ArchiveWriter<W> {
pub fn new(mut writer: W) -> Result<Self> {
writer.seek(std::io::SeekFrom::Start(SIGNATURE_HEADER_SIZE))?;
Ok(Self {
output: writer,
files: Default::default(),
content_methods: Arc::new(vec![EncoderConfiguration::new(EncoderMethod::LZMA2)]),
pack_info: Default::default(),
unpack_info: Default::default(),
encrypt_header: true,
})
}
pub fn auto_finish(self) -> AutoFinisher<Self> {
AutoFinisher(Some(self))
}
pub fn set_content_methods(&mut self, content_methods: Vec<EncoderConfiguration>) -> &mut Self {
if content_methods.is_empty() {
return self;
}
self.content_methods = Arc::new(content_methods);
self
}
pub fn set_encrypt_header(&mut self, enabled: bool) {
self.encrypt_header = enabled;
}
pub fn push_archive_entry<R: Read>(
&mut self,
mut entry: ArchiveEntry,
reader: Option<R>,
) -> Result<&ArchiveEntry> {
if !entry.is_directory {
if let Some(mut r) = reader {
let mut compressed_len = 0;
let mut compressed = CompressWrapWriter::new(&mut self.output, &mut compressed_len);
let mut more_sizes: Vec<Rc<Cell<usize>>> =
Vec::with_capacity(self.content_methods.len() - 1);
let (crc, size) = {
let mut w = Self::create_writer(
&self.content_methods,
&mut compressed,
&mut more_sizes,
)?;
let mut write_len = 0;
let mut w = CompressWrapWriter::new(&mut w, &mut write_len);
let mut buf = [0u8; 4096];
loop {
match r.read(&mut buf) {
Ok(n) => {
if n == 0 {
break;
}
w.write_all(&buf[..n]).map_err(|e| {
Error::io_msg(e, format!("Encode entry:{}", entry.name()))
})?;
}
Err(e) => {
return Err(Error::io_msg(
e,
format!("Encode entry:{}", entry.name()),
));
}
}
}
w.flush()
.map_err(|e| Error::io_msg(e, format!("Encode entry:{}", entry.name())))?;
w.write(&[])
.map_err(|e| Error::io_msg(e, format!("Encode entry:{}", entry.name())))?;
(w.crc_value(), write_len)
};
let compressed_crc = compressed.crc_value();
entry.has_stream = true;
entry.size = size as u64;
entry.crc = crc as u64;
entry.has_crc = true;
entry.compressed_crc = compressed_crc as u64;
entry.compressed_size = compressed_len as u64;
self.pack_info
.add_stream(compressed_len as u64, compressed_crc);
let mut sizes = Vec::with_capacity(more_sizes.len() + 1);
sizes.extend(more_sizes.iter().map(|s| s.get() as u64));
sizes.push(size as u64);
self.unpack_info
.add(self.content_methods.clone(), sizes, crc);
self.files.push(entry);
return Ok(self.files.last().unwrap());
}
}
entry.has_stream = false;
entry.size = 0;
entry.compressed_size = 0;
entry.has_crc = false;
self.files.push(entry);
Ok(self.files.last().unwrap())
}
pub fn push_archive_entries<R: Read>(
&mut self,
entries: Vec<ArchiveEntry>,
reader: Vec<SourceReader<R>>,
) -> Result<&mut Self> {
let mut entries = entries;
let mut r = SeqReader::new(reader);
assert_eq!(r.reader_len(), entries.len());
let mut compressed_len = 0;
let mut compressed = CompressWrapWriter::new(&mut self.output, &mut compressed_len);
let content_methods = &self.content_methods;
let mut more_sizes: Vec<Rc<Cell<usize>>> = Vec::with_capacity(content_methods.len() - 1);
let (crc, size) = {
let mut w = Self::create_writer(content_methods, &mut compressed, &mut more_sizes)?;
let mut write_len = 0;
let mut w = CompressWrapWriter::new(&mut w, &mut write_len);
let mut buf = [0u8; 4096];
fn entries_names(entries: &[ArchiveEntry]) -> String {
let mut names = String::with_capacity(512);
for ele in entries.iter() {
names.push_str(&ele.name);
names.push(';');
if names.len() > 512 {
break;
}
}
names
}
loop {
match r.read(&mut buf) {
Ok(n) => {
if n == 0 {
break;
}
w.write_all(&buf[..n]).map_err(|e| {
Error::io_msg(e, format!("Encode entries:{}", entries_names(&entries)))
})?;
}
Err(e) => {
return Err(Error::io_msg(
e,
format!("Encode entries:{}", entries_names(&entries)),
));
}
}
}
w.flush().map_err(|e| {
let mut names = String::with_capacity(512);
for ele in entries.iter() {
names.push_str(&ele.name);
names.push(';');
if names.len() > 512 {
break;
}
}
Error::io_msg(e, format!("Encode entry:{names}"))
})?;
w.write(&[]).map_err(|e| {
Error::io_msg(e, format!("Encode entry:{}", entries_names(&entries)))
})?;
(w.crc_value(), write_len)
};
let compressed_crc = compressed.crc_value();
let mut sub_stream_crcs = Vec::with_capacity(entries.len());
let mut sub_stream_sizes = Vec::with_capacity(entries.len());
for i in 0..entries.len() {
let entry = &mut entries[i];
let ri = &r[i];
entry.crc = ri.crc_value() as u64;
entry.size = ri.read_count() as u64;
sub_stream_crcs.push(entry.crc as u32);
sub_stream_sizes.push(entry.size);
entry.has_crc = true;
}
self.pack_info
.add_stream(compressed_len as u64, compressed_crc);
let mut sizes = Vec::with_capacity(more_sizes.len() + 1);
sizes.extend(more_sizes.iter().map(|s| s.get() as u64));
sizes.push(size as u64);
self.unpack_info.add_multiple(
content_methods.clone(),
sizes,
crc,
entries.len() as u64,
sub_stream_sizes,
sub_stream_crcs,
);
self.files.extend(entries);
Ok(self)
}
fn create_writer<'a, O: Write + 'a>(
methods: &[EncoderConfiguration],
out: O,
more_sized: &mut Vec<Rc<Cell<usize>>>,
) -> Result<Box<dyn Write + 'a>> {
let mut encoder: Box<dyn Write> = Box::new(out);
let mut first = true;
for mc in methods.iter() {
if !first {
let counting = CountingWriter::new(encoder);
more_sized.push(counting.counting());
encoder = Box::new(encoder::add_encoder(counting, mc)?);
} else {
let counting = CountingWriter::new(encoder);
encoder = Box::new(encoder::add_encoder(counting, mc)?);
}
first = false;
}
Ok(encoder)
}
pub fn finish(mut self) -> std::io::Result<W> {
let mut header: Vec<u8> = Vec::with_capacity(64 * 1024);
self.write_encoded_header(&mut header)?;
let header_pos = self.output.stream_position()?;
self.output.write_all(&header)?;
let crc32 = crc32fast::hash(&header);
let mut hh = [0u8; SIGNATURE_HEADER_SIZE as usize];
{
let mut hhw = hh.as_mut_slice();
hhw.write_all(SEVEN_Z_SIGNATURE)?;
hhw.write_u8(0)?;
hhw.write_u8(4)?;
hhw.write_u32(0)?;
hhw.write_u64(header_pos - SIGNATURE_HEADER_SIZE)?;
hhw.write_u64(0xFFFFFFFF & header.len() as u64)?;
hhw.write_u32(crc32)?;
}
let crc32 = crc32fast::hash(&hh[12..]);
hh[8..12].copy_from_slice(&crc32.to_le_bytes());
self.output.seek(std::io::SeekFrom::Start(0))?;
self.output.write_all(&hh)?;
self.output.flush()?;
Ok(self.output)
}
fn write_header<H: Write>(&mut self, header: &mut H) -> std::io::Result<()> {
header.write_u8(K_HEADER)?;
header.write_u8(K_MAIN_STREAMS_INFO)?;
self.write_streams_info(header)?;
self.write_files_info(header)?;
header.write_u8(K_END)?;
Ok(())
}
fn write_encoded_header<H: Write>(&mut self, header: &mut H) -> std::io::Result<()> {
let mut raw_header = Vec::with_capacity(64 * 1024);
self.write_header(&mut raw_header)?;
let mut pack_info = PackInfo::default();
let position = self.output.stream_position()?;
let pos = position - SIGNATURE_HEADER_SIZE;
pack_info.pos = pos;
let mut more_sizes = vec![];
let size = raw_header.len() as u64;
let crc32 = crc32fast::hash(&raw_header);
let mut methods = vec![];
let mut must_encrypt_header = false;
if self.encrypt_header {
for conf in self.content_methods.iter() {
if conf.method.id() == EncoderMethod::AES256_SHA256.id() {
methods.push(conf.clone());
must_encrypt_header = true;
break;
}
}
}
methods.push(EncoderConfiguration::new(EncoderMethod::LZMA));
let methods = Arc::new(methods);
let mut encoded_data = Vec::with_capacity(size as usize / 2);
let mut compress_size = 0;
let mut compressed = CompressWrapWriter::new(&mut encoded_data, &mut compress_size);
{
let mut encoder = Self::create_writer(&methods, &mut compressed, &mut more_sizes)
.map_err(std::io::Error::other)?;
encoder.write_all(&raw_header)?;
encoder.flush()?;
let _ = encoder.write(&[])?;
}
let compress_crc = compressed.crc_value();
let compress_size = *compressed.bytes_written;
if !must_encrypt_header && compress_size as u64 + 20 >= size {
header.write_all(&raw_header)?;
return Ok(());
}
self.output.write_all(&encoded_data[..compress_size])?;
pack_info.add_stream(compress_size as u64, compress_crc);
let mut unpack_info = UnpackInfo::default();
let mut sizes = Vec::with_capacity(1 + more_sizes.len());
sizes.extend(more_sizes.iter().map(|s| s.get() as u64));
sizes.push(size);
unpack_info.add(methods, sizes, crc32);
header.write_u8(K_ENCODED_HEADER)?;
pack_info.write_to(header)?;
unpack_info.write_to(header)?;
unpack_info.write_substreams(header)?;
header.write_u8(K_END)?;
Ok(())
}
fn write_streams_info<H: Write>(&mut self, header: &mut H) -> std::io::Result<()> {
if self.pack_info.len() > 0 {
self.pack_info.write_to(header)?;
self.unpack_info.write_to(header)?;
}
self.unpack_info.write_substreams(header)?;
header.write_u8(K_END)?;
Ok(())
}
fn write_files_info<H: Write>(&self, header: &mut H) -> std::io::Result<()> {
header.write_u8(K_FILES_INFO)?;
write_u64(header, self.files.len() as u64)?;
self.write_file_empty_streams(header)?;
self.write_file_empty_files(header)?;
self.write_file_anti_items(header)?;
self.write_file_names(header)?;
self.write_file_ctimes(header)?;
self.write_file_atimes(header)?;
self.write_file_mtimes(header)?;
self.write_file_windows_attrs(header)?;
header.write_u8(K_END)?;
Ok(())
}
fn write_file_empty_streams<H: Write>(&self, header: &mut H) -> std::io::Result<()> {
let mut has_empty = false;
for entry in self.files.iter() {
if !entry.has_stream {
has_empty = true;
break;
}
}
if has_empty {
header.write_u8(K_EMPTY_STREAM)?;
let mut bitset = BitSet::with_capacity(self.files.len());
for (i, entry) in self.files.iter().enumerate() {
if !entry.has_stream {
bitset.insert(i);
}
}
let mut temp: Vec<u8> = Vec::with_capacity(bitset.len() / 8 + 1);
write_bit_set(&mut temp, &bitset)?;
write_u64(header, temp.len() as u64)?;
header.write_all(temp.as_slice())?;
}
Ok(())
}
fn write_file_empty_files<H: Write>(&self, header: &mut H) -> std::io::Result<()> {
let mut has_empty = false;
let mut empty_stream_counter = 0;
let mut bitset = BitSet::new();
for entry in self.files.iter() {
if !entry.has_stream {
let is_dir = entry.is_directory();
has_empty |= !is_dir;
if !is_dir {
bitset.insert(empty_stream_counter);
}
empty_stream_counter += 1;
}
}
if has_empty {
header.write_u8(K_EMPTY_FILE)?;
let mut temp: Vec<u8> = Vec::with_capacity(bitset.len() / 8 + 1);
write_bit_set(&mut temp, &bitset)?;
write_u64(header, temp.len() as u64)?;
header.write_all(&temp)?;
}
Ok(())
}
fn write_file_anti_items<H: Write>(&self, header: &mut H) -> std::io::Result<()> {
let mut has_anti = false;
let mut counter = 0;
let mut bitset = BitSet::new();
for entry in self.files.iter() {
if !entry.has_stream {
let is_anti = entry.is_anti_item();
has_anti |= !is_anti;
if !is_anti {
bitset.insert(counter);
}
counter += 1;
}
}
if has_anti {
header.write_u8(K_ANTI)?;
let mut temp: Vec<u8> = Vec::with_capacity(bitset.len() / 8 + 1);
write_bit_set(&mut temp, &bitset)?;
write_u64(header, temp.len() as u64)?;
header.write_all(temp.as_slice())?;
}
Ok(())
}
fn write_file_names<H: Write>(&self, header: &mut H) -> std::io::Result<()> {
header.write_u8(K_NAME)?;
let mut temp: Vec<u8> = Vec::with_capacity(128);
let out = &mut temp;
out.write_u8(0)?;
for file in self.files.iter() {
for c in file.name().encode_utf16() {
let buf = c.to_le_bytes();
out.write_all(&buf)?;
}
out.write_all(&[0u8; 2])?;
}
write_u64(header, temp.len() as u64)?;
header.write_all(temp.as_slice())?;
Ok(())
}
write_times!(
write_file_ctimes,
K_C_TIME,
has_creation_date,
creation_date
);
write_times!(write_file_atimes, K_A_TIME, has_access_date, access_date);
write_times!(
write_file_mtimes,
K_M_TIME,
has_last_modified_date,
last_modified_date
);
write_times!(
write_file_windows_attrs,
K_WIN_ATTRIBUTES,
has_windows_attributes,
windows_attributes,
write_u32
);
}
impl<W: Write + Seek> AutoFinish for ArchiveWriter<W> {
fn finish_ignore_error(self) {
let _ = self.finish();
}
}
pub(crate) fn write_u64<W: Write>(header: &mut W, mut value: u64) -> std::io::Result<()> {
let mut first = 0;
let mut mask = 0x80;
let mut i = 0;
while i < 8 {
if value < (1u64 << (7 * (i + 1))) {
first |= value >> (8 * i);
break;
}
first |= mask;
mask >>= 1;
i += 1;
}
header.write_u8((first & 0xFF) as u8)?;
while i > 0 {
header.write_u8((value & 0xFF) as u8)?;
value >>= 8;
i -= 1;
}
Ok(())
}
struct CompressWrapWriter<'a, W> {
writer: W,
crc: Hasher,
cache: Vec<u8>,
bytes_written: &'a mut usize,
}
impl<'a, W: Write> CompressWrapWriter<'a, W> {
pub fn new(writer: W, bytes_written: &'a mut usize) -> Self {
Self {
writer,
crc: Hasher::new(),
cache: Vec::with_capacity(8192),
bytes_written,
}
}
pub fn crc_value(&mut self) -> u32 {
let crc = std::mem::replace(&mut self.crc, Hasher::new());
crc.finalize()
}
}
impl<W: Write> Write for CompressWrapWriter<'_, W> {
fn write(&mut self, buf: &[u8]) -> std::io::Result<usize> {
self.cache.resize(buf.len(), Default::default());
let len = self.writer.write(buf)?;
self.crc.update(&buf[..len]);
*self.bytes_written += len;
Ok(len)
}
fn flush(&mut self) -> std::io::Result<()> {
self.writer.flush()
}
}