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compress.cc
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compress.cc
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/*
* Copyright (C) 2016 ScyllaDB
*/
/*
* This file is part of Scylla.
*
* Scylla is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Scylla is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Scylla. If not, see <http://www.gnu.org/licenses/>.
*/
#include <lz4.h>
#include <zlib.h>
#include <snappy-c.h>
#include "compress.hh"
#include "utils/class_registrator.hh"
const sstring compressor::namespace_prefix = "org.apache.cassandra.io.compress.";
class lz4_processor: public compressor {
public:
using compressor::compressor;
size_t uncompress(const char* input, size_t input_len, char* output,
size_t output_len) const override;
size_t compress(const char* input, size_t input_len, char* output,
size_t output_len) const override;
size_t compress_max_size(size_t input_len) const override;
};
class snappy_processor: public compressor {
public:
using compressor::compressor;
size_t uncompress(const char* input, size_t input_len, char* output,
size_t output_len) const override;
size_t compress(const char* input, size_t input_len, char* output,
size_t output_len) const override;
size_t compress_max_size(size_t input_len) const override;
};
class deflate_processor: public compressor {
public:
using compressor::compressor;
size_t uncompress(const char* input, size_t input_len, char* output,
size_t output_len) const override;
size_t compress(const char* input, size_t input_len, char* output,
size_t output_len) const override;
size_t compress_max_size(size_t input_len) const override;
};
compressor::compressor(sstring name)
: _name(std::move(name))
{}
std::set<sstring> compressor::option_names() const {
return {};
}
std::map<sstring, sstring> compressor::options() const {
return {};
}
shared_ptr<compressor> compressor::create(const sstring& name, const opt_getter& opts) {
if (name.empty()) {
return {};
}
qualified_name qn(namespace_prefix, name);
for (auto& c : { lz4, snappy, deflate }) {
if (c->name() == qn) {
return c;
}
}
return compressor_registry::create(qn, opts);
}
shared_ptr<compressor> compressor::create(const std::map<sstring, sstring>& options) {
auto i = options.find(compression_parameters::SSTABLE_COMPRESSION);
if (i != options.end() && !i->second.empty()) {
return create(i->second, [&options](const sstring& key) -> opt_string {
auto i = options.find(key);
if (i == options.end()) {
return std::nullopt;
}
return { i->second };
});
}
return {};
}
thread_local const shared_ptr<compressor> compressor::lz4 = make_shared<lz4_processor>(namespace_prefix + "LZ4Compressor");
thread_local const shared_ptr<compressor> compressor::snappy = make_shared<snappy_processor>(namespace_prefix + "SnappyCompressor");
thread_local const shared_ptr<compressor> compressor::deflate = make_shared<deflate_processor>(namespace_prefix + "DeflateCompressor");
const sstring compression_parameters::SSTABLE_COMPRESSION = "sstable_compression";
const sstring compression_parameters::CHUNK_LENGTH_KB = "chunk_length_in_kb";
const sstring compression_parameters::CHUNK_LENGTH_KB_ERR = "chunk_length_kb";
const sstring compression_parameters::CRC_CHECK_CHANCE = "crc_check_chance";
compression_parameters::compression_parameters()
: compression_parameters(compressor::lz4)
{}
compression_parameters::~compression_parameters()
{}
compression_parameters::compression_parameters(compressor_ptr c)
: _compressor(std::move(c))
{}
compression_parameters::compression_parameters(const std::map<sstring, sstring>& options) {
_compressor = compressor::create(options);
validate_options(options);
auto chunk_length = options.find(CHUNK_LENGTH_KB) != options.end() ?
options.find(CHUNK_LENGTH_KB) : options.find(CHUNK_LENGTH_KB_ERR);
if (chunk_length != options.end()) {
try {
_chunk_length = std::stoi(chunk_length->second) * 1024;
} catch (const std::exception& e) {
throw exceptions::syntax_exception(sstring("Invalid integer value ") + chunk_length->second + " for " + chunk_length->first);
}
}
auto crc_chance = options.find(CRC_CHECK_CHANCE);
if (crc_chance != options.end()) {
try {
_crc_check_chance = std::stod(crc_chance->second);
} catch (const std::exception& e) {
throw exceptions::syntax_exception(sstring("Invalid double value ") + crc_chance->second + "for " + CRC_CHECK_CHANCE);
}
}
}
void compression_parameters::validate() {
if (_chunk_length) {
auto chunk_length = _chunk_length.value();
if (chunk_length <= 0) {
throw exceptions::configuration_exception(
fmt::sprintf("Invalid negative or null for %s/%s", CHUNK_LENGTH_KB, CHUNK_LENGTH_KB_ERR));
}
// _chunk_length must be a power of two
if (chunk_length & (chunk_length - 1)) {
throw exceptions::configuration_exception(
fmt::sprintf("%s/%s must be a power of 2.", CHUNK_LENGTH_KB, CHUNK_LENGTH_KB_ERR));
}
}
if (_crc_check_chance && (_crc_check_chance.value() < 0.0 || _crc_check_chance.value() > 1.0)) {
throw exceptions::configuration_exception(sstring(CRC_CHECK_CHANCE) + " must be between 0.0 and 1.0.");
}
}
std::map<sstring, sstring> compression_parameters::get_options() const {
if (!_compressor) {
return std::map<sstring, sstring>();
}
auto opts = _compressor->options();
opts.emplace(compression_parameters::SSTABLE_COMPRESSION, _compressor->name());
if (_chunk_length) {
opts.emplace(sstring(CHUNK_LENGTH_KB), std::to_string(_chunk_length.value() / 1024));
}
if (_crc_check_chance) {
opts.emplace(sstring(CRC_CHECK_CHANCE), std::to_string(_crc_check_chance.value()));
}
return opts;
}
bool compression_parameters::operator==(const compression_parameters& other) const {
return _compressor == other._compressor
&& _chunk_length == other._chunk_length
&& _crc_check_chance == other._crc_check_chance;
}
bool compression_parameters::operator!=(const compression_parameters& other) const {
return !(*this == other);
}
void compression_parameters::validate_options(const std::map<sstring, sstring>& options) {
// currently, there are no options specific to a particular compressor
static std::set<sstring> keywords({
sstring(SSTABLE_COMPRESSION),
sstring(CHUNK_LENGTH_KB),
sstring(CHUNK_LENGTH_KB_ERR),
sstring(CRC_CHECK_CHANCE),
});
std::set<sstring> ckw;
if (_compressor) {
ckw = _compressor->option_names();
}
for (auto&& opt : options) {
if (!keywords.count(opt.first) && !ckw.count(opt.first)) {
throw exceptions::configuration_exception(format("Unknown compression option '{}'.", opt.first));
}
}
}
size_t lz4_processor::uncompress(const char* input, size_t input_len,
char* output, size_t output_len) const {
// We use LZ4_decompress_safe(). According to the documentation, the
// function LZ4_decompress_fast() is slightly faster, but maliciously
// crafted compressed data can cause it to overflow the output buffer.
// Theoretically, our compressed data is created by us so is not malicious
// (and accidental corruption is avoided by the compressed-data checksum),
// but let's not take that chance for now, until we've actually measured
// the performance benefit that LZ4_decompress_fast() would bring.
// Cassandra's LZ4Compressor prepends to the chunk its uncompressed length
// in 4 bytes little-endian (!) order. We don't need this information -
// we already know the uncompressed data is at most the given chunk size
// (and usually is exactly that, except in the last chunk). The advance
// knowledge of the uncompressed size could be useful if we used
// LZ4_decompress_fast(), but we prefer LZ4_decompress_safe() anyway...
input += 4;
input_len -= 4;
auto ret = LZ4_decompress_safe(input, output, input_len, output_len);
if (ret < 0) {
throw std::runtime_error("LZ4 uncompression failure");
}
return ret;
}
size_t lz4_processor::compress(const char* input, size_t input_len,
char* output, size_t output_len) const {
if (output_len < LZ4_COMPRESSBOUND(input_len) + 4) {
throw std::runtime_error("LZ4 compression failure: length of output is too small");
}
// Write input_len (32-bit data) to beginning of output in little-endian representation.
output[0] = input_len & 0xFF;
output[1] = (input_len >> 8) & 0xFF;
output[2] = (input_len >> 16) & 0xFF;
output[3] = (input_len >> 24) & 0xFF;
#ifdef HAVE_LZ4_COMPRESS_DEFAULT
auto ret = LZ4_compress_default(input, output + 4, input_len, LZ4_compressBound(input_len));
#else
auto ret = LZ4_compress(input, output + 4, input_len);
#endif
if (ret == 0) {
throw std::runtime_error("LZ4 compression failure: LZ4_compress() failed");
}
return ret + 4;
}
size_t lz4_processor::compress_max_size(size_t input_len) const {
return LZ4_COMPRESSBOUND(input_len) + 4;
}
size_t deflate_processor::uncompress(const char* input,
size_t input_len, char* output, size_t output_len) const {
z_stream zs;
zs.zalloc = Z_NULL;
zs.zfree = Z_NULL;
zs.opaque = Z_NULL;
zs.avail_in = 0;
zs.next_in = Z_NULL;
if (inflateInit(&zs) != Z_OK) {
throw std::runtime_error("deflate uncompression init failure");
}
// yuck, zlib is not const-correct, and also uses unsigned char while we use char :-(
zs.next_in = reinterpret_cast<unsigned char*>(const_cast<char*>(input));
zs.avail_in = input_len;
zs.next_out = reinterpret_cast<unsigned char*>(output);
zs.avail_out = output_len;
auto res = inflate(&zs, Z_FINISH);
inflateEnd(&zs);
if (res == Z_STREAM_END) {
return output_len - zs.avail_out;
} else {
throw std::runtime_error("deflate uncompression failure");
}
}
size_t deflate_processor::compress(const char* input,
size_t input_len, char* output, size_t output_len) const {
z_stream zs;
zs.zalloc = Z_NULL;
zs.zfree = Z_NULL;
zs.opaque = Z_NULL;
zs.avail_in = 0;
zs.next_in = Z_NULL;
if (deflateInit(&zs, Z_DEFAULT_COMPRESSION) != Z_OK) {
throw std::runtime_error("deflate compression init failure");
}
zs.next_in = reinterpret_cast<unsigned char*>(const_cast<char*>(input));
zs.avail_in = input_len;
zs.next_out = reinterpret_cast<unsigned char*>(output);
zs.avail_out = output_len;
auto res = ::deflate(&zs, Z_FINISH);
deflateEnd(&zs);
if (res == Z_STREAM_END) {
return output_len - zs.avail_out;
} else {
throw std::runtime_error("deflate compression failure");
}
}
size_t deflate_processor::compress_max_size(size_t input_len) const {
z_stream zs;
zs.zalloc = Z_NULL;
zs.zfree = Z_NULL;
zs.opaque = Z_NULL;
zs.avail_in = 0;
zs.next_in = Z_NULL;
if (deflateInit(&zs, Z_DEFAULT_COMPRESSION) != Z_OK) {
throw std::runtime_error("deflate compression init failure");
}
auto res = deflateBound(&zs, input_len);
deflateEnd(&zs);
return res;
}
size_t snappy_processor::uncompress(const char* input, size_t input_len,
char* output, size_t output_len) const {
if (snappy_uncompress(input, input_len, output, &output_len)
== SNAPPY_OK) {
return output_len;
} else {
throw std::runtime_error("snappy uncompression failure");
}
}
size_t snappy_processor::compress(const char* input, size_t input_len,
char* output, size_t output_len) const {
auto ret = snappy_compress(input, input_len, output, &output_len);
if (ret != SNAPPY_OK) {
throw std::runtime_error("snappy compression failure: snappy_compress() failed");
}
return output_len;
}
size_t snappy_processor::compress_max_size(size_t input_len) const {
return snappy_max_compressed_length(input_len);
}