mozilla-central/third_party/rust/miniz_oxide/src/inflate/stream.rs

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//! Extra streaming decompression functionality.
//!
//! As of now this is mainly intended for use to build a higher-level wrapper.
#[cfg(feature = "with-alloc")]
use crate::alloc::boxed::Box;
use core::{cmp, mem};
use crate::inflate::core::{decompress, inflate_flags, DecompressorOxide, TINFL_LZ_DICT_SIZE};
use crate::inflate::TINFLStatus;
use crate::{DataFormat, MZError, MZFlush, MZResult, MZStatus, StreamResult};
/// Tag that determines reset policy of [InflateState](struct.InflateState.html)
pub trait ResetPolicy {
/// Performs reset
fn reset(&self, state: &mut InflateState);
}
/// Resets state, without performing expensive ops (e.g. zeroing buffer)
///
/// Note that not zeroing buffer can lead to security issues when dealing with untrusted input.
pub struct MinReset;
impl ResetPolicy for MinReset {
fn reset(&self, state: &mut InflateState) {
state.decompressor().init();
state.dict_ofs = 0;
state.dict_avail = 0;
state.first_call = true;
state.has_flushed = false;
state.last_status = TINFLStatus::NeedsMoreInput;
}
}
/// Resets state and zero memory, continuing to use the same data format.
pub struct ZeroReset;
impl ResetPolicy for ZeroReset {
#[inline]
fn reset(&self, state: &mut InflateState) {
MinReset.reset(state);
state.dict = [0; TINFL_LZ_DICT_SIZE];
}
}
/// Full reset of the state, including zeroing memory.
///
/// Requires to provide new data format.
pub struct FullReset(pub DataFormat);
impl ResetPolicy for FullReset {
#[inline]
fn reset(&self, state: &mut InflateState) {
ZeroReset.reset(state);
state.data_format = self.0;
}
}
/// A struct that compbines a decompressor with extra data for streaming decompression.
///
pub struct InflateState {
/// Inner decompressor struct
decomp: DecompressorOxide,
/// Buffer of input bytes for matches.
/// TODO: Could probably do this a bit cleaner with some
/// Cursor-like class.
/// We may also look into whether we need to keep a buffer here, or just one in the
/// decompressor struct.
dict: [u8; TINFL_LZ_DICT_SIZE],
/// Where in the buffer are we currently at?
dict_ofs: usize,
/// How many bytes of data to be flushed is there currently in the buffer?
dict_avail: usize,
first_call: bool,
has_flushed: bool,
/// Whether the input data is wrapped in a zlib header and checksum.
/// TODO: This should be stored in the decompressor.
data_format: DataFormat,
last_status: TINFLStatus,
}
impl Default for InflateState {
fn default() -> Self {
InflateState {
decomp: DecompressorOxide::default(),
dict: [0; TINFL_LZ_DICT_SIZE],
dict_ofs: 0,
dict_avail: 0,
first_call: true,
has_flushed: false,
data_format: DataFormat::Raw,
last_status: TINFLStatus::NeedsMoreInput,
}
}
}
impl InflateState {
/// Create a new state.
///
/// Note that this struct is quite large due to internal buffers, and as such storing it on
/// the stack is not recommended.
///
/// # Parameters
/// `data_format`: Determines whether the compressed data is assumed to wrapped with zlib
/// metadata.
pub fn new(data_format: DataFormat) -> InflateState {
InflateState {
data_format,
..Default::default()
}
}
/// Create a new state on the heap.
///
/// # Parameters
/// `data_format`: Determines whether the compressed data is assumed to wrapped with zlib
/// metadata.
#[cfg(feature = "with-alloc")]
pub fn new_boxed(data_format: DataFormat) -> Box<InflateState> {
let mut b: Box<InflateState> = Box::default();
b.data_format = data_format;
b
}
/// Access the innner decompressor.
pub fn decompressor(&mut self) -> &mut DecompressorOxide {
&mut self.decomp
}
/// Return the status of the last call to `inflate` with this `InflateState`.
pub const fn last_status(&self) -> TINFLStatus {
self.last_status
}
/// Create a new state using miniz/zlib style window bits parameter.
///
/// The decompressor does not support different window sizes. As such,
/// any positive (>0) value will set the zlib header flag, while a negative one
/// will not.
#[cfg(feature = "with-alloc")]
pub fn new_boxed_with_window_bits(window_bits: i32) -> Box<InflateState> {
let mut b: Box<InflateState> = Box::default();
b.data_format = DataFormat::from_window_bits(window_bits);
b
}
#[inline]
/// Reset the decompressor without re-allocating memory, using the given
/// data format.
pub fn reset(&mut self, data_format: DataFormat) {
self.reset_as(FullReset(data_format));
}
#[inline]
/// Resets the state according to specified policy.
pub fn reset_as<T: ResetPolicy>(&mut self, policy: T) {
policy.reset(self)
}
}
/// Try to decompress from `input` to `output` with the given [`InflateState`]
///
/// # `flush`
///
/// Generally, the various [`MZFlush`] flags have meaning only on the compression side. They can be
/// supplied here, but the only one that has any semantic meaning is [`MZFlush::Finish`], which is a
/// signal that the stream is expected to finish, and failing to do so is an error. It isn't
/// necessary to specify it when the stream ends; you'll still get returned a
/// [`MZStatus::StreamEnd`] anyway. Other values either have no effect or cause errors. It's
/// likely that you'll almost always just want to use [`MZFlush::None`].
///
/// # Errors
///
/// Returns [`MZError::Buf`] if the size of the `output` slice is empty or no progress was made due
/// to lack of expected input data, or if called with [`MZFlush::Finish`] and input wasn't all
/// consumed.
///
/// Returns [`MZError::Data`] if this or a a previous call failed with an error return from
/// [`TINFLStatus`]; probably indicates corrupted data.
///
/// Returns [`MZError::Stream`] when called with [`MZFlush::Full`] (meaningless on
/// decompression), or when called without [`MZFlush::Finish`] after an earlier call with
/// [`MZFlush::Finish`] has been made.
pub fn inflate(
state: &mut InflateState,
input: &[u8],
output: &mut [u8],
flush: MZFlush,
) -> StreamResult {
let mut bytes_consumed = 0;
let mut bytes_written = 0;
let mut next_in = input;
let mut next_out = output;
if flush == MZFlush::Full {
return StreamResult::error(MZError::Stream);
}
let mut decomp_flags = if state.data_format == DataFormat::Zlib {
inflate_flags::TINFL_FLAG_COMPUTE_ADLER32
} else {
inflate_flags::TINFL_FLAG_IGNORE_ADLER32
};
if (state.data_format == DataFormat::Zlib)
| (state.data_format == DataFormat::ZLibIgnoreChecksum)
{
decomp_flags |= inflate_flags::TINFL_FLAG_PARSE_ZLIB_HEADER;
}
let first_call = state.first_call;
state.first_call = false;
if (state.last_status as i32) < 0 {
return StreamResult::error(MZError::Data);
}
if state.has_flushed && (flush != MZFlush::Finish) {
return StreamResult::error(MZError::Stream);
}
state.has_flushed |= flush == MZFlush::Finish;
if (flush == MZFlush::Finish) && first_call {
decomp_flags |= inflate_flags::TINFL_FLAG_USING_NON_WRAPPING_OUTPUT_BUF;
let status = decompress(&mut state.decomp, next_in, next_out, 0, decomp_flags);
let in_bytes = status.1;
let out_bytes = status.2;
let status = status.0;
state.last_status = status;
bytes_consumed += in_bytes;
bytes_written += out_bytes;
let ret_status = {
if (status as i32) < 0 {
Err(MZError::Data)
} else if status != TINFLStatus::Done {
state.last_status = TINFLStatus::Failed;
Err(MZError::Buf)
} else {
Ok(MZStatus::StreamEnd)
}
};
return StreamResult {
bytes_consumed,
bytes_written,
status: ret_status,
};
}
if flush != MZFlush::Finish {
decomp_flags |= inflate_flags::TINFL_FLAG_HAS_MORE_INPUT;
}
if state.dict_avail != 0 {
bytes_written += push_dict_out(state, &mut next_out);
return StreamResult {
bytes_consumed,
bytes_written,
status: Ok(
if (state.last_status == TINFLStatus::Done) && (state.dict_avail == 0) {
MZStatus::StreamEnd
} else {
MZStatus::Ok
},
),
};
}
let status = inflate_loop(
state,
&mut next_in,
&mut next_out,
&mut bytes_consumed,
&mut bytes_written,
decomp_flags,
flush,
);
StreamResult {
bytes_consumed,
bytes_written,
status,
}
}
fn inflate_loop(
state: &mut InflateState,
next_in: &mut &[u8],
next_out: &mut &mut [u8],
total_in: &mut usize,
total_out: &mut usize,
decomp_flags: u32,
flush: MZFlush,
) -> MZResult {
let orig_in_len = next_in.len();
loop {
let status = decompress(
&mut state.decomp,
*next_in,
&mut state.dict,
state.dict_ofs,
decomp_flags,
);
let in_bytes = status.1;
let out_bytes = status.2;
let status = status.0;
state.last_status = status;
*next_in = &next_in[in_bytes..];
*total_in += in_bytes;
state.dict_avail = out_bytes;
*total_out += push_dict_out(state, next_out);
// The stream was corrupted, and decompression failed.
if (status as i32) < 0 {
return Err(MZError::Data);
}
// The decompressor has flushed all it's data and is waiting for more input, but
// there was no more input provided.
if (status == TINFLStatus::NeedsMoreInput) && orig_in_len == 0 {
return Err(MZError::Buf);
}
if flush == MZFlush::Finish {
if status == TINFLStatus::Done {
// There is not enough space in the output buffer to flush the remaining
// decompressed data in the internal buffer.
return if state.dict_avail != 0 {
Err(MZError::Buf)
} else {
Ok(MZStatus::StreamEnd)
};
// No more space in the output buffer, but we're not done.
} else if next_out.is_empty() {
return Err(MZError::Buf);
}
} else {
// We're not expected to finish, so it's fine if we can't flush everything yet.
let empty_buf = next_in.is_empty() || next_out.is_empty();
if (status == TINFLStatus::Done) || empty_buf || (state.dict_avail != 0) {
return if (status == TINFLStatus::Done) && (state.dict_avail == 0) {
// No more data left, we're done.
Ok(MZStatus::StreamEnd)
} else {
// Ok for now, still waiting for more input data or output space.
Ok(MZStatus::Ok)
};
}
}
}
}
fn push_dict_out(state: &mut InflateState, next_out: &mut &mut [u8]) -> usize {
let n = cmp::min(state.dict_avail as usize, next_out.len());
(next_out[..n]).copy_from_slice(&state.dict[state.dict_ofs..state.dict_ofs + n]);
*next_out = &mut mem::take(next_out)[n..];
state.dict_avail -= n;
state.dict_ofs = (state.dict_ofs + (n)) & (TINFL_LZ_DICT_SIZE - 1);
n
}
#[cfg(test)]
mod test {
use super::{inflate, InflateState};
use crate::{DataFormat, MZFlush, MZStatus};
use alloc::vec;
#[test]
fn test_state() {
let encoded = [
120u8, 156, 243, 72, 205, 201, 201, 215, 81, 168, 202, 201, 76, 82, 4, 0, 27, 101, 4,
19,
];
let mut out = vec![0; 50];
let mut state = InflateState::new_boxed(DataFormat::Zlib);
let res = inflate(&mut state, &encoded, &mut out, MZFlush::Finish);
let status = res.status.expect("Failed to decompress!");
assert_eq!(status, MZStatus::StreamEnd);
assert_eq!(out[..res.bytes_written as usize], b"Hello, zlib!"[..]);
assert_eq!(res.bytes_consumed, encoded.len());
state.reset_as(super::ZeroReset);
out.iter_mut().map(|x| *x = 0).count();
let res = inflate(&mut state, &encoded, &mut out, MZFlush::Finish);
let status = res.status.expect("Failed to decompress!");
assert_eq!(status, MZStatus::StreamEnd);
assert_eq!(out[..res.bytes_written as usize], b"Hello, zlib!"[..]);
assert_eq!(res.bytes_consumed, encoded.len());
state.reset_as(super::MinReset);
out.iter_mut().map(|x| *x = 0).count();
let res = inflate(&mut state, &encoded, &mut out, MZFlush::Finish);
let status = res.status.expect("Failed to decompress!");
assert_eq!(status, MZStatus::StreamEnd);
assert_eq!(out[..res.bytes_written as usize], b"Hello, zlib!"[..]);
assert_eq!(res.bytes_consumed, encoded.len());
assert_eq!(state.decompressor().adler32(), Some(459605011));
// Test state when not computing adler.
state = InflateState::new_boxed(DataFormat::ZLibIgnoreChecksum);
out.iter_mut().map(|x| *x = 0).count();
let res = inflate(&mut state, &encoded, &mut out, MZFlush::Finish);
let status = res.status.expect("Failed to decompress!");
assert_eq!(status, MZStatus::StreamEnd);
assert_eq!(out[..res.bytes_written as usize], b"Hello, zlib!"[..]);
assert_eq!(res.bytes_consumed, encoded.len());
// Not computed, so should be Some(1)
assert_eq!(state.decompressor().adler32(), Some(1));
// Should still have the checksum read from the header file.
assert_eq!(state.decompressor().adler32_header(), Some(459605011))
}
}