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serenity/Userland/Libraries/LibCompress/Deflate.cpp
Andreas Kling 5d180d1f99 Everywhere: Rename ASSERT => VERIFY 
(...and ASSERT_NOT_REACHED => VERIFY_NOT_REACHED)

Since all of these checks are done in release builds as well,
let's rename them to VERIFY to prevent confusion, as everyone is
used to assertions being compiled out in release.

We can introduce a new ASSERT macro that is specifically for debug
checks, but I'm doing this wholesale conversion first since we've
accumulated thousands of these already, and it's not immediately
obvious which ones are suitable for ASSERT.
2021-02-23 20:56:54 +01:00

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/*
* Copyright (c) 2020, the SerenityOS developers
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <AK/Array.h>
#include <AK/Assertions.h>
#include <AK/BinarySearch.h>
#include <AK/LogStream.h>
#include <AK/MemoryStream.h>
#include <LibCompress/Deflate.h>
namespace Compress {
const CanonicalCode& CanonicalCode::fixed_literal_codes()
{
static CanonicalCode code;
static bool initialized = false;
if (initialized)
return code;
Array<u8, 288> data;
data.span().slice(0, 144 - 0).fill(8);
data.span().slice(144, 256 - 144).fill(9);
data.span().slice(256, 280 - 256).fill(7);
data.span().slice(280, 288 - 280).fill(8);
code = CanonicalCode::from_bytes(data).value();
initialized = true;
return code;
}
const CanonicalCode& CanonicalCode::fixed_distance_codes()
{
static CanonicalCode code;
static bool initialized = false;
if (initialized)
return code;
Array<u8, 32> data;
data.span().fill(5);
code = CanonicalCode::from_bytes(data).value();
initialized = true;
return code;
}
Optional<CanonicalCode> CanonicalCode::from_bytes(ReadonlyBytes bytes)
{
// FIXME: I can't quite follow the algorithm here, but it seems to work.
CanonicalCode code;
auto next_code = 0;
for (size_t code_length = 1; code_length <= 15; ++code_length) {
next_code <<= 1;
auto start_bit = 1 << code_length;
for (size_t symbol = 0; symbol < bytes.size(); ++symbol) {
if (bytes[symbol] != code_length)
continue;
if (next_code > start_bit)
return {};
code.m_symbol_codes.append(start_bit | next_code);
code.m_symbol_values.append(symbol);
next_code++;
}
}
if (next_code != (1 << 15)) {
return {};
}
return code;
}
u32 CanonicalCode::read_symbol(InputBitStream& stream) const
{
u32 code_bits = 1;
for (;;) {
code_bits = code_bits << 1 | stream.read_bits(1);
VERIFY(code_bits < (1 << 16));
// FIXME: This is very inefficient and could greatly be improved by implementing this
// algorithm: https://www.hanshq.net/zip.html#huffdec
size_t index;
if (AK::binary_search(m_symbol_codes.span(), code_bits, &index))
return m_symbol_values[index];
}
}
DeflateDecompressor::CompressedBlock::CompressedBlock(DeflateDecompressor& decompressor, CanonicalCode literal_codes, Optional<CanonicalCode> distance_codes)
: m_decompressor(decompressor)
, m_literal_codes(literal_codes)
, m_distance_codes(distance_codes)
{
}
bool DeflateDecompressor::CompressedBlock::try_read_more()
{
if (m_eof == true)
return false;
const auto symbol = m_literal_codes.read_symbol(m_decompressor.m_input_stream);
if (symbol < 256) {
m_decompressor.m_output_stream << static_cast<u8>(symbol);
return true;
} else if (symbol == 256) {
m_eof = true;
return false;
} else {
if (!m_distance_codes.has_value()) {
m_decompressor.set_fatal_error();
return false;
}
const auto length = m_decompressor.decode_length(symbol);
const auto distance = m_decompressor.decode_distance(m_distance_codes.value().read_symbol(m_decompressor.m_input_stream));
for (size_t idx = 0; idx < length; ++idx) {
u8 byte = 0;
m_decompressor.m_output_stream.read({ &byte, sizeof(byte) }, distance);
m_decompressor.m_output_stream << byte;
}
return true;
}
}
DeflateDecompressor::UncompressedBlock::UncompressedBlock(DeflateDecompressor& decompressor, size_t length)
: m_decompressor(decompressor)
, m_bytes_remaining(length)
{
}
bool DeflateDecompressor::UncompressedBlock::try_read_more()
{
if (m_bytes_remaining == 0)
return false;
const auto nread = min(m_bytes_remaining, m_decompressor.m_output_stream.remaining_contigous_space());
m_bytes_remaining -= nread;
m_decompressor.m_input_stream >> m_decompressor.m_output_stream.reserve_contigous_space(nread);
return true;
}
DeflateDecompressor::DeflateDecompressor(InputStream& stream)
: m_input_stream(stream)
{
}
DeflateDecompressor::~DeflateDecompressor()
{
if (m_state == State::ReadingCompressedBlock)
m_compressed_block.~CompressedBlock();
if (m_state == State::ReadingUncompressedBlock)
m_uncompressed_block.~UncompressedBlock();
}
size_t DeflateDecompressor::read(Bytes bytes)
{
if (has_any_error())
return 0;
if (m_state == State::Idle) {
if (m_read_final_bock)
return 0;
m_read_final_bock = m_input_stream.read_bit();
const auto block_type = m_input_stream.read_bits(2);
if (block_type == 0b00) {
m_input_stream.align_to_byte_boundary();
LittleEndian<u16> length, negated_length;
m_input_stream >> length >> negated_length;
if ((length ^ 0xffff) != negated_length) {
set_fatal_error();
return 0;
}
m_state = State::ReadingUncompressedBlock;
new (&m_uncompressed_block) UncompressedBlock(*this, length);
return read(bytes);
}
if (block_type == 0b01) {
m_state = State::ReadingCompressedBlock;
new (&m_compressed_block) CompressedBlock(*this, CanonicalCode::fixed_literal_codes(), CanonicalCode::fixed_distance_codes());
return read(bytes);
}
if (block_type == 0b10) {
CanonicalCode literal_codes;
Optional<CanonicalCode> distance_codes;
decode_codes(literal_codes, distance_codes);
m_state = State::ReadingCompressedBlock;
new (&m_compressed_block) CompressedBlock(*this, literal_codes, distance_codes);
return read(bytes);
}
set_fatal_error();
return 0;
}
if (m_state == State::ReadingCompressedBlock) {
auto nread = m_output_stream.read(bytes);
while (nread < bytes.size() && m_compressed_block.try_read_more()) {
nread += m_output_stream.read(bytes.slice(nread));
}
if (nread == bytes.size())
return nread;
m_compressed_block.~CompressedBlock();
m_state = State::Idle;
return nread + read(bytes.slice(nread));
}
if (m_state == State::ReadingUncompressedBlock) {
auto nread = m_output_stream.read(bytes);
while (nread < bytes.size() && m_uncompressed_block.try_read_more()) {
nread += m_output_stream.read(bytes.slice(nread));
}
if (nread == bytes.size())
return nread;
m_uncompressed_block.~UncompressedBlock();
m_state = State::Idle;
return nread + read(bytes.slice(nread));
}
VERIFY_NOT_REACHED();
}
bool DeflateDecompressor::read_or_error(Bytes bytes)
{
if (read(bytes) < bytes.size()) {
set_fatal_error();
return false;
}
return true;
}
bool DeflateDecompressor::discard_or_error(size_t count)
{
u8 buffer[4096];
size_t ndiscarded = 0;
while (ndiscarded < count) {
if (unreliable_eof()) {
set_fatal_error();
return false;
}
ndiscarded += read({ buffer, min<size_t>(count - ndiscarded, 4096) });
}
return true;
}
bool DeflateDecompressor::unreliable_eof() const { return m_state == State::Idle && m_read_final_bock; }
Optional<ByteBuffer> DeflateDecompressor::decompress_all(ReadonlyBytes bytes)
{
InputMemoryStream memory_stream { bytes };
DeflateDecompressor deflate_stream { memory_stream };
DuplexMemoryStream output_stream;
u8 buffer[4096];
while (!deflate_stream.has_any_error() && !deflate_stream.unreliable_eof()) {
const auto nread = deflate_stream.read({ buffer, sizeof(buffer) });
output_stream.write_or_error({ buffer, nread });
}
if (deflate_stream.handle_any_error())
return {};
return output_stream.copy_into_contiguous_buffer();
}
u32 DeflateDecompressor::decode_length(u32 symbol)
{
// FIXME: I can't quite follow the algorithm here, but it seems to work.
if (symbol <= 264)
return symbol - 254;
if (symbol <= 284) {
auto extra_bits = (symbol - 261) / 4;
return (((symbol - 265) % 4 + 4) << extra_bits) + 3 + m_input_stream.read_bits(extra_bits);
}
if (symbol == 285)
return 258;
VERIFY_NOT_REACHED();
}
u32 DeflateDecompressor::decode_distance(u32 symbol)
{
// FIXME: I can't quite follow the algorithm here, but it seems to work.
if (symbol <= 3)
return symbol + 1;
if (symbol <= 29) {
auto extra_bits = (symbol / 2) - 1;
return ((symbol % 2 + 2) << extra_bits) + 1 + m_input_stream.read_bits(extra_bits);
}
VERIFY_NOT_REACHED();
}
void DeflateDecompressor::decode_codes(CanonicalCode& literal_code, Optional<CanonicalCode>& distance_code)
{
auto literal_code_count = m_input_stream.read_bits(5) + 257;
auto distance_code_count = m_input_stream.read_bits(5) + 1;
auto code_length_count = m_input_stream.read_bits(4) + 4;
// First we have to extract the code lengths of the code that was used to encode the code lengths of
// the code that was used to encode the block.
u8 code_lengths_code_lengths[19] = { 0 };
for (size_t i = 0; i < code_length_count; ++i) {
static const size_t indices[] { 16, 17, 18, 0, 8, 7, 9, 6, 10, 5, 11, 4, 12, 3, 13, 2, 14, 1, 15 };
code_lengths_code_lengths[indices[i]] = m_input_stream.read_bits(3);
}
// Now we can extract the code that was used to encode the code lengths of the code that was used to
// encode the block.
auto code_length_code_result = CanonicalCode::from_bytes({ code_lengths_code_lengths, sizeof(code_lengths_code_lengths) });
if (!code_length_code_result.has_value()) {
set_fatal_error();
return;
}
const auto code_length_code = code_length_code_result.value();
// Next we extract the code lengths of the code that was used to encode the block.
Vector<u8> code_lengths;
while (code_lengths.size() < literal_code_count + distance_code_count) {
auto symbol = code_length_code.read_symbol(m_input_stream);
if (symbol <= 15) {
code_lengths.append(static_cast<u8>(symbol));
continue;
} else if (symbol == 17) {
auto nrepeat = 3 + m_input_stream.read_bits(3);
for (size_t j = 0; j < nrepeat; ++j)
code_lengths.append(0);
continue;
} else if (symbol == 18) {
auto nrepeat = 11 + m_input_stream.read_bits(7);
for (size_t j = 0; j < nrepeat; ++j)
code_lengths.append(0);
continue;
} else {
VERIFY(symbol == 16);
if (code_lengths.is_empty()) {
set_fatal_error();
return;
}
auto nrepeat = 3 + m_input_stream.read_bits(2);
for (size_t j = 0; j < nrepeat; ++j)
code_lengths.append(code_lengths.last());
}
}
if (code_lengths.size() != literal_code_count + distance_code_count) {
set_fatal_error();
return;
}
// Now we extract the code that was used to encode literals and lengths in the block.
auto literal_code_result = CanonicalCode::from_bytes(code_lengths.span().trim(literal_code_count));
if (!literal_code_result.has_value()) {
set_fatal_error();
return;
}
literal_code = literal_code_result.value();
// Now we extract the code that was used to encode distances in the block.
if (distance_code_count == 1) {
auto length = code_lengths[literal_code_count];
if (length == 0) {
return;
} else if (length != 1) {
set_fatal_error();
return;
}
}
auto distance_code_result = CanonicalCode::from_bytes(code_lengths.span().slice(literal_code_count));
if (!distance_code_result.has_value()) {
set_fatal_error();
return;
}
distance_code = distance_code_result.value();
}
}
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