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|
use super::super::blocks::block::BlockHeader;
use super::super::blocks::block::BlockType;
use super::super::blocks::literals_section::LiteralsSection;
use super::super::blocks::literals_section::LiteralsSectionType;
use super::super::blocks::sequence_section::SequencesHeader;
use super::literals_section_decoder::{decode_literals, DecompressLiteralsError};
use super::sequence_execution::ExecuteSequencesError;
use super::sequence_section_decoder::decode_sequences;
use super::sequence_section_decoder::DecodeSequenceError;
use crate::blocks::literals_section::LiteralsSectionParseError;
use crate::blocks::sequence_section::SequencesHeaderParseError;
use crate::decoding::scratch::DecoderScratch;
use crate::decoding::sequence_execution::execute_sequences;
use std::io::{self, Read};
pub struct BlockDecoder {
header_buffer: [u8; 3],
internal_state: DecoderState,
}
enum DecoderState {
ReadyToDecodeNextHeader,
ReadyToDecodeNextBody,
#[allow(dead_code)]
Failed, //TODO put "self.internal_state = DecoderState::Failed;" everywhere an unresolvable error occurs
}
#[derive(Debug, thiserror::Error)]
#[non_exhaustive]
pub enum BlockHeaderReadError {
#[error("Error while reading the block header")]
ReadError(#[from] io::Error),
#[error("Reserved block occured. This is considered corruption by the documentation")]
FoundReservedBlock,
#[error("Error getting block type: {0}")]
BlockTypeError(#[from] BlockTypeError),
#[error("Error getting block content size: {0}")]
BlockSizeError(#[from] BlockSizeError),
}
#[derive(Debug, thiserror::Error)]
#[non_exhaustive]
pub enum BlockTypeError {
#[error(
"Invalid Blocktype number. Is: {num} Should be one of: 0, 1, 2, 3 (3 is reserved though"
)]
InvalidBlocktypeNumber { num: u8 },
}
#[derive(Debug, thiserror::Error)]
#[non_exhaustive]
pub enum BlockSizeError {
#[error("Blocksize was bigger than the absolute maximum {ABSOLUTE_MAXIMUM_BLOCK_SIZE} (128kb). Is: {size}")]
BlockSizeTooLarge { size: u32 },
}
#[derive(Debug, thiserror::Error)]
#[non_exhaustive]
pub enum DecompressBlockError {
#[error("Error while reading the block content: {0}")]
BlockContentReadError(#[from] io::Error),
#[error("Malformed section header. Says literals would be this long: {expected_len} but there are only {remaining_bytes} bytes left")]
MalformedSectionHeader {
expected_len: usize,
remaining_bytes: usize,
},
#[error(transparent)]
DecompressLiteralsError(#[from] DecompressLiteralsError),
#[error(transparent)]
LiteralsSectionParseError(#[from] LiteralsSectionParseError),
#[error(transparent)]
SequencesHeaderParseError(#[from] SequencesHeaderParseError),
#[error(transparent)]
DecodeSequenceError(#[from] DecodeSequenceError),
#[error(transparent)]
ExecuteSequencesError(#[from] ExecuteSequencesError),
}
#[derive(Debug, thiserror::Error)]
#[non_exhaustive]
pub enum DecodeBlockContentError {
#[error("Can't decode next block if failed along the way. Results will be nonsense")]
DecoderStateIsFailed,
#[error("Cant decode next block body, while expecting to decode the header of the previous block. Results will be nonsense")]
ExpectedHeaderOfPreviousBlock,
#[error("Error while reading bytes for {step}: {source}")]
ReadError {
step: BlockType,
#[source]
source: io::Error,
},
#[error(transparent)]
DecompressBlockError(#[from] DecompressBlockError),
}
pub fn new() -> BlockDecoder {
BlockDecoder {
internal_state: DecoderState::ReadyToDecodeNextHeader,
header_buffer: [0u8; 3],
}
}
const ABSOLUTE_MAXIMUM_BLOCK_SIZE: u32 = 128 * 1024;
impl BlockDecoder {
pub fn decode_block_content(
&mut self,
header: &BlockHeader,
workspace: &mut DecoderScratch, //reuse this as often as possible. Not only if the trees are reused but also reuse the allocations when building new trees
mut source: impl Read,
) -> Result<u64, DecodeBlockContentError> {
match self.internal_state {
DecoderState::ReadyToDecodeNextBody => { /* Happy :) */ }
DecoderState::Failed => return Err(DecodeBlockContentError::DecoderStateIsFailed),
DecoderState::ReadyToDecodeNextHeader => {
return Err(DecodeBlockContentError::ExpectedHeaderOfPreviousBlock)
}
}
let block_type = header.block_type;
match block_type {
BlockType::RLE => {
const BATCH_SIZE: usize = 512;
let mut buf = [0u8; BATCH_SIZE];
let full_reads = header.decompressed_size / BATCH_SIZE as u32;
let single_read_size = header.decompressed_size % BATCH_SIZE as u32;
source.read_exact(&mut buf[0..1]).map_err(|err| {
DecodeBlockContentError::ReadError {
step: block_type,
source: err,
}
})?;
self.internal_state = DecoderState::ReadyToDecodeNextHeader;
for i in 1..BATCH_SIZE {
buf[i] = buf[0];
}
for _ in 0..full_reads {
workspace.buffer.push(&buf[..]);
}
let smaller = &mut buf[..single_read_size as usize];
workspace.buffer.push(smaller);
Ok(1)
}
BlockType::Raw => {
const BATCH_SIZE: usize = 128 * 1024;
let mut buf = [0u8; BATCH_SIZE];
let full_reads = header.decompressed_size / BATCH_SIZE as u32;
let single_read_size = header.decompressed_size % BATCH_SIZE as u32;
for _ in 0..full_reads {
source.read_exact(&mut buf[..]).map_err(|err| {
DecodeBlockContentError::ReadError {
step: block_type,
source: err,
}
})?;
workspace.buffer.push(&buf[..]);
}
let smaller = &mut buf[..single_read_size as usize];
source
.read_exact(smaller)
.map_err(|err| DecodeBlockContentError::ReadError {
step: block_type,
source: err,
})?;
workspace.buffer.push(smaller);
self.internal_state = DecoderState::ReadyToDecodeNextHeader;
Ok(u64::from(header.decompressed_size))
}
BlockType::Reserved => {
panic!("How did you even get this. The decoder should error out if it detects a reserved-type block");
}
BlockType::Compressed => {
self.decompress_block(header, workspace, source)?;
self.internal_state = DecoderState::ReadyToDecodeNextHeader;
Ok(u64::from(header.content_size))
}
}
}
fn decompress_block(
&mut self,
header: &BlockHeader,
workspace: &mut DecoderScratch, //reuse this as often as possible. Not only if the trees are reused but also reuse the allocations when building new trees
mut source: impl Read,
) -> Result<(), DecompressBlockError> {
workspace
.block_content_buffer
.resize(header.content_size as usize, 0);
source.read_exact(workspace.block_content_buffer.as_mut_slice())?;
let raw = workspace.block_content_buffer.as_slice();
let mut section = LiteralsSection::new();
let bytes_in_literals_header = section.parse_from_header(raw)?;
let raw = &raw[bytes_in_literals_header as usize..];
if crate::VERBOSE {
println!(
"Found {} literalssection with regenerated size: {}, and compressed size: {:?}",
section.ls_type, section.regenerated_size, section.compressed_size
);
}
let upper_limit_for_literals = match section.compressed_size {
Some(x) => x as usize,
None => match section.ls_type {
LiteralsSectionType::RLE => 1,
LiteralsSectionType::Raw => section.regenerated_size as usize,
_ => panic!("Bug in this library"),
},
};
if raw.len() < upper_limit_for_literals {
return Err(DecompressBlockError::MalformedSectionHeader {
expected_len: upper_limit_for_literals,
remaining_bytes: raw.len(),
});
}
let raw_literals = &raw[..upper_limit_for_literals];
if crate::VERBOSE {
println!("Slice for literals: {}", raw_literals.len());
}
workspace.literals_buffer.clear(); //all literals of the previous block must have been used in the sequence execution anyways. just be defensive here
let bytes_used_in_literals_section = decode_literals(
§ion,
&mut workspace.huf,
raw_literals,
&mut workspace.literals_buffer,
)?;
assert!(
section.regenerated_size == workspace.literals_buffer.len() as u32,
"Wrong number of literals: {}, Should have been: {}",
workspace.literals_buffer.len(),
section.regenerated_size
);
assert!(bytes_used_in_literals_section == upper_limit_for_literals as u32);
let raw = &raw[upper_limit_for_literals..];
if crate::VERBOSE {
println!("Slice for sequences with headers: {}", raw.len());
}
let mut seq_section = SequencesHeader::new();
let bytes_in_sequence_header = seq_section.parse_from_header(raw)?;
let raw = &raw[bytes_in_sequence_header as usize..];
if crate::VERBOSE {
println!(
"Found sequencessection with sequences: {} and size: {}",
seq_section.num_sequences,
raw.len()
);
}
assert!(
u32::from(bytes_in_literals_header)
+ bytes_used_in_literals_section
+ u32::from(bytes_in_sequence_header)
+ raw.len() as u32
== header.content_size
);
if crate::VERBOSE {
println!("Slice for sequences: {}", raw.len());
}
if seq_section.num_sequences != 0 {
decode_sequences(
&seq_section,
raw,
&mut workspace.fse,
&mut workspace.sequences,
)?;
if crate::VERBOSE {
println!("Executing sequences");
}
execute_sequences(workspace)?;
} else {
workspace.buffer.push(&workspace.literals_buffer);
workspace.sequences.clear();
}
Ok(())
}
pub fn read_block_header(
&mut self,
mut r: impl Read,
) -> Result<(BlockHeader, u8), BlockHeaderReadError> {
//match self.internal_state {
// DecoderState::ReadyToDecodeNextHeader => {/* Happy :) */},
// DecoderState::Failed => return Err(format!("Cant decode next block if failed along the way. Results will be nonsense")),
// DecoderState::ReadyToDecodeNextBody => return Err(format!("Cant decode next block header, while expecting to decode the body of the previous block. Results will be nonsense")),
//}
r.read_exact(&mut self.header_buffer[0..3])?;
let btype = self.block_type()?;
if let BlockType::Reserved = btype {
return Err(BlockHeaderReadError::FoundReservedBlock);
}
let block_size = self.block_content_size()?;
let decompressed_size = match btype {
BlockType::Raw => block_size,
BlockType::RLE => block_size,
BlockType::Reserved => 0, //should be catched above, this is an error state
BlockType::Compressed => 0, //unknown but will be smaller than 128kb (or window_size if that is smaller than 128kb)
};
let content_size = match btype {
BlockType::Raw => block_size,
BlockType::Compressed => block_size,
BlockType::RLE => 1,
BlockType::Reserved => 0, //should be catched above, this is an error state
};
let last_block = self.is_last();
self.reset_buffer();
self.internal_state = DecoderState::ReadyToDecodeNextBody;
//just return 3. Blockheaders always take 3 bytes
Ok((
BlockHeader {
last_block,
block_type: btype,
decompressed_size,
content_size,
},
3,
))
}
fn reset_buffer(&mut self) {
self.header_buffer[0] = 0;
self.header_buffer[1] = 0;
self.header_buffer[2] = 0;
}
fn is_last(&self) -> bool {
self.header_buffer[0] & 0x1 == 1
}
fn block_type(&self) -> Result<BlockType, BlockTypeError> {
let t = (self.header_buffer[0] >> 1) & 0x3;
match t {
0 => Ok(BlockType::Raw),
1 => Ok(BlockType::RLE),
2 => Ok(BlockType::Compressed),
3 => Ok(BlockType::Reserved),
other => Err(BlockTypeError::InvalidBlocktypeNumber { num: other }),
}
}
fn block_content_size(&self) -> Result<u32, BlockSizeError> {
let val = self.block_content_size_unchecked();
if val > ABSOLUTE_MAXIMUM_BLOCK_SIZE {
Err(BlockSizeError::BlockSizeTooLarge { size: val })
} else {
Ok(val)
}
}
fn block_content_size_unchecked(&self) -> u32 {
u32::from(self.header_buffer[0] >> 3) //push out type and last_block flags. Retain 5 bit
| (u32::from(self.header_buffer[1]) << 5)
| (u32::from(self.header_buffer[2]) << 13)
}
}
|