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#[cfg(test)]
extern crate flate2;
extern crate adler32;
extern crate byteorder;
mod compression_options;
mod huffman_table;
mod lz77;
mod lzvalue;
mod chained_hash_table;
mod length_encode;
mod output_writer;
mod stored_block;
mod huffman_lengths;
mod zlib;
mod checksum;
mod bit_reverse;
mod bitstream;
mod encoder_state;
mod matching;
mod input_buffer;
mod deflate_state;
mod compress;
mod writer;
#[cfg(test)]
mod test_utils;
use std::io::Write;
use std::io;
use byteorder::BigEndian;
use checksum::RollingChecksum;
use deflate_state::DeflateState;
use compress::compress_data_dynamic_n;
#[doc(hidden)]
pub use lz77::lz77_compress;
pub use compression_options::{CompressionOptions, SpecialOptions, Compression};
use compress::Flush;
pub use lz77::MatchingType;
pub mod write {
pub use writer::{DeflateEncoder, ZlibEncoder};
}
fn compress_data_dynamic<RC: RollingChecksum, W: Write>(input: &[u8],
writer: &mut W,
mut checksum: RC,
compression_options: CompressionOptions)
-> io::Result<usize> {
checksum.update_from_slice(input);
let mut deflate_state = Box::new(DeflateState::new(compression_options, writer));
compress_data_dynamic_n(input, &mut deflate_state, Flush::Finish)
}
pub fn deflate_bytes_conf<O: Into<CompressionOptions>>(input: &[u8], options: O) -> Vec<u8> {
let mut writer = Vec::with_capacity(input.len() / 3);
compress_data_dynamic(input,
&mut writer,
checksum::NoChecksum::new(),
options.into())
.expect("Write error!");
writer
}
pub fn deflate_bytes(input: &[u8]) -> Vec<u8> {
deflate_bytes_conf(input, Compression::Default)
}
pub fn deflate_bytes_zlib_conf<O: Into<CompressionOptions>>(input: &[u8], options: O) -> Vec<u8> {
use byteorder::WriteBytesExt;
let mut writer = Vec::with_capacity(input.len() / 3);
zlib::write_zlib_header(&mut writer, zlib::CompressionLevel::Default)
.expect("Write error when writing zlib header!");
let mut checksum = checksum::Adler32Checksum::new();
compress_data_dynamic(input, &mut writer, &mut checksum, options.into())
.expect("Write error when writing compressed data!");
let hash = checksum.current_hash();
writer.write_u32::<BigEndian>(hash).expect("Write error when writing checksum!");
writer
}
pub fn deflate_bytes_zlib(input: &[u8]) -> Vec<u8> {
deflate_bytes_zlib_conf(input, Compression::Default)
}
#[cfg(test)]
mod test {
use super::*;
use std::io::Write;
use test_utils::{get_test_data, decompress_to_end, decompress_zlib};
fn chunked_write<W: Write>(mut writer: W, data: &[u8], chunk_size: usize) {
for chunk in data.chunks(chunk_size) {
let bytes_written = writer.write(&chunk).unwrap();
assert_eq!(bytes_written, chunk.len());
}
}
#[test]
fn dynamic_string_mem() {
use std::str;
let test_data = String::from(" GNU GENERAL PUBLIC LICENSE").into_bytes();
let compressed = deflate_bytes(&test_data);
assert!(compressed.len() < test_data.len());
let result = decompress_to_end(&compressed);
assert_eq!(test_data, result);
}
#[test]
fn dynamic_string_file() {
use std::str;
let input = get_test_data();
let compressed = deflate_bytes(&input);
println!("Compressed len: {}", compressed.len());
let result = decompress_to_end(&compressed);
assert!(input == result);
assert!(compressed.len() < input.len());
}
#[test]
fn file_zlib() {
let test_data = get_test_data();
let compressed = deflate_bytes_zlib(&test_data);
println!("compressed length: {}", compressed.len());
let result = decompress_zlib(&compressed);
assert!(&test_data == &result);
assert!(compressed.len() < test_data.len());
}
#[test]
fn zlib_short() {
let test_data = [10, 20, 30, 40, 55];
let compressed = deflate_bytes_zlib(&test_data);
let result = decompress_zlib(&compressed);
assert_eq!(&test_data, result.as_slice());
}
#[test]
fn zlib_last_block() {
let mut test_data = vec![22; 32768];
test_data.extend(&[5, 2, 55, 11, 12]);
let compressed = deflate_bytes_zlib(&test_data);
let result = decompress_zlib(&compressed);
assert!(test_data == result);
}
fn chunk_test(chunk_size: usize) {
let mut compressed = Vec::with_capacity(32000);
let data = get_test_data();
{
let mut compressor = write::ZlibEncoder::new(&mut compressed,
CompressionOptions::high());
chunked_write(&mut compressor, &data, chunk_size);
compressor.finish().unwrap();
}
let compressed2 = deflate_bytes_zlib_conf(&data, CompressionOptions::high());
let res = decompress_zlib(&compressed);
assert!(res == data);
assert_eq!(compressed.len(), compressed2.len());
assert!(compressed == compressed2);
}
#[test]
fn zlib_writer_chunks() {
use input_buffer::BUFFER_SIZE;
chunk_test(1);
chunk_test(50);
chunk_test(400);
chunk_test(32768);
chunk_test(BUFFER_SIZE);
chunk_test(50000);
chunk_test((32768 * 2) + 258);
}
}