// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). // // Copyright (c) 2011 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. // #pragma once #include #include #include #include "rocksdb/options.h" #include "rocksdb/table.h" #include "util/cache_allocator.h" #include "util/coding.h" #include "util/compression_context_cache.h" #ifdef SNAPPY #include #endif #ifdef ZLIB #include #endif #ifdef BZIP2 #include #endif #if defined(LZ4) #include #include #endif #if defined(ZSTD) #include #if ZSTD_VERSION_NUMBER >= 10103 // v1.1.3+ #include #endif // ZSTD_VERSION_NUMBER >= 10103 namespace rocksdb { // Need this for the context allocation override // On windows we need to do this explicitly #if (ZSTD_VERSION_NUMBER >= 500) #if defined(ROCKSDB_JEMALLOC) && defined(OS_WIN) && \ defined(ZSTD_STATIC_LINKING_ONLY) #define ROCKSDB_ZSTD_CUSTOM_MEM namespace port { ZSTD_customMem GetJeZstdAllocationOverrides(); } // namespace port #endif // defined(ROCKSDB_JEMALLOC) && defined(OS_WIN) && // defined(ZSTD_STATIC_LINKING_ONLY) // Cached data represents a portion that can be re-used // If, in the future we have more than one native context to // cache we can arrange this as a tuple class ZSTDUncompressCachedData { public: using ZSTDNativeContext = ZSTD_DCtx*; ZSTDUncompressCachedData() {} // Init from cache ZSTDUncompressCachedData(const ZSTDUncompressCachedData& o) = delete; ZSTDUncompressCachedData& operator=(const ZSTDUncompressCachedData&) = delete; ZSTDUncompressCachedData(ZSTDUncompressCachedData&& o) ROCKSDB_NOEXCEPT : ZSTDUncompressCachedData() { *this = std::move(o); } ZSTDUncompressCachedData& operator=(ZSTDUncompressCachedData&& o) ROCKSDB_NOEXCEPT { assert(zstd_ctx_ == nullptr); std::swap(zstd_ctx_, o.zstd_ctx_); std::swap(cache_idx_, o.cache_idx_); return *this; } ZSTDNativeContext Get() const { return zstd_ctx_; } int64_t GetCacheIndex() const { return cache_idx_; } void CreateIfNeeded() { if (zstd_ctx_ == nullptr) { #ifdef ROCKSDB_ZSTD_CUSTOM_MEM zstd_ctx_ = ZSTD_createDCtx_advanced(port::GetJeZstdAllocationOverrides()); #else // ROCKSDB_ZSTD_CUSTOM_MEM zstd_ctx_ = ZSTD_createDCtx(); #endif // ROCKSDB_ZSTD_CUSTOM_MEM cache_idx_ = -1; } } void InitFromCache(const ZSTDUncompressCachedData& o, int64_t idx) { zstd_ctx_ = o.zstd_ctx_; cache_idx_ = idx; } ~ZSTDUncompressCachedData() { if (zstd_ctx_ != nullptr && cache_idx_ == -1) { ZSTD_freeDCtx(zstd_ctx_); } } private: ZSTDNativeContext zstd_ctx_ = nullptr; int64_t cache_idx_ = -1; // -1 means this instance owns the context }; #endif // (ZSTD_VERSION_NUMBER >= 500) } // namespace rocksdb #endif // ZSTD #if !(defined ZSTD) || !(ZSTD_VERSION_NUMBER >= 500) namespace rocksdb { class ZSTDUncompressCachedData { void* padding; // unused public: using ZSTDNativeContext = void*; ZSTDUncompressCachedData() {} ZSTDUncompressCachedData(const ZSTDUncompressCachedData&) {} ZSTDUncompressCachedData& operator=(const ZSTDUncompressCachedData&) = delete; ZSTDUncompressCachedData(ZSTDUncompressCachedData&&) ROCKSDB_NOEXCEPT = default; ZSTDUncompressCachedData& operator=(ZSTDUncompressCachedData&&) ROCKSDB_NOEXCEPT = default; ZSTDNativeContext Get() const { return nullptr; } int64_t GetCacheIndex() const { return -1; } void CreateIfNeeded() {} void InitFromCache(const ZSTDUncompressCachedData&, int64_t) {} private: void ignore_padding__() { padding = nullptr; } }; } // namespace rocksdb #endif #if defined(XPRESS) #include "port/xpress.h" #endif namespace rocksdb { // Instantiate this class and pass it to the uncompression API below class CompressionContext { private: const CompressionType type_; const CompressionOptions opts_; Slice dict_; #if defined(ZSTD) && (ZSTD_VERSION_NUMBER >= 500) ZSTD_CCtx* zstd_ctx_ = nullptr; void CreateNativeContext() { if (type_ == kZSTD || type_ == kZSTDNotFinalCompression) { #ifdef ROCKSDB_ZSTD_CUSTOM_MEM zstd_ctx_ = ZSTD_createCCtx_advanced(port::GetJeZstdAllocationOverrides()); #else // ROCKSDB_ZSTD_CUSTOM_MEM zstd_ctx_ = ZSTD_createCCtx(); #endif // ROCKSDB_ZSTD_CUSTOM_MEM } } void DestroyNativeContext() { if (zstd_ctx_ != nullptr) { ZSTD_freeCCtx(zstd_ctx_); } } public: // callable inside ZSTD_Compress ZSTD_CCtx* ZSTDPreallocCtx() const { assert(type_ == kZSTD || type_ == kZSTDNotFinalCompression); return zstd_ctx_; } #else // ZSTD && (ZSTD_VERSION_NUMBER >= 500) private: void CreateNativeContext() {} void DestroyNativeContext() {} #endif // ZSTD && (ZSTD_VERSION_NUMBER >= 500) public: explicit CompressionContext(CompressionType comp_type) : type_(comp_type) { CreateNativeContext(); } CompressionContext(CompressionType comp_type, const CompressionOptions& opts, const Slice& comp_dict = Slice()) : type_(comp_type), opts_(opts), dict_(comp_dict) { CreateNativeContext(); } ~CompressionContext() { DestroyNativeContext(); } CompressionContext(const CompressionContext&) = delete; CompressionContext& operator=(const CompressionContext&) = delete; const CompressionOptions& options() const { return opts_; } CompressionType type() const { return type_; } const Slice& dict() const { return dict_; } Slice& dict() { return dict_; } }; // Instantiate this class and pass it to the uncompression API below class UncompressionContext { private: CompressionType type_; Slice dict_; CompressionContextCache* ctx_cache_ = nullptr; ZSTDUncompressCachedData uncomp_cached_data_; public: struct NoCache {}; // Do not use context cache, used by TableBuilder UncompressionContext(NoCache, CompressionType comp_type) : type_(comp_type) {} explicit UncompressionContext(CompressionType comp_type) : UncompressionContext(comp_type, Slice()) {} UncompressionContext(CompressionType comp_type, const Slice& comp_dict) : type_(comp_type), dict_(comp_dict) { if (type_ == kZSTD || type_ == kZSTDNotFinalCompression) { ctx_cache_ = CompressionContextCache::Instance(); uncomp_cached_data_ = ctx_cache_->GetCachedZSTDUncompressData(); } } ~UncompressionContext() { if ((type_ == kZSTD || type_ == kZSTDNotFinalCompression) && uncomp_cached_data_.GetCacheIndex() != -1) { assert(ctx_cache_ != nullptr); ctx_cache_->ReturnCachedZSTDUncompressData( uncomp_cached_data_.GetCacheIndex()); } } UncompressionContext(const UncompressionContext&) = delete; UncompressionContext& operator=(const UncompressionContext&) = delete; ZSTDUncompressCachedData::ZSTDNativeContext GetZSTDContext() const { return uncomp_cached_data_.Get(); } CompressionType type() const { return type_; } const Slice& dict() const { return dict_; } Slice& dict() { return dict_; } }; inline bool Snappy_Supported() { #ifdef SNAPPY return true; #else return false; #endif } inline bool Zlib_Supported() { #ifdef ZLIB return true; #else return false; #endif } inline bool BZip2_Supported() { #ifdef BZIP2 return true; #else return false; #endif } inline bool LZ4_Supported() { #ifdef LZ4 return true; #else return false; #endif } inline bool XPRESS_Supported() { #ifdef XPRESS return true; #else return false; #endif } inline bool ZSTD_Supported() { #ifdef ZSTD // ZSTD format is finalized since version 0.8.0. return (ZSTD_versionNumber() >= 800); #else return false; #endif } inline bool ZSTDNotFinal_Supported() { #ifdef ZSTD return true; #else return false; #endif } inline bool CompressionTypeSupported(CompressionType compression_type) { switch (compression_type) { case kNoCompression: return true; case kSnappyCompression: return Snappy_Supported(); case kZlibCompression: return Zlib_Supported(); case kBZip2Compression: return BZip2_Supported(); case kLZ4Compression: return LZ4_Supported(); case kLZ4HCCompression: return LZ4_Supported(); case kXpressCompression: return XPRESS_Supported(); case kZSTDNotFinalCompression: return ZSTDNotFinal_Supported(); case kZSTD: return ZSTD_Supported(); default: assert(false); return false; } } inline std::string CompressionTypeToString(CompressionType compression_type) { switch (compression_type) { case kNoCompression: return "NoCompression"; case kSnappyCompression: return "Snappy"; case kZlibCompression: return "Zlib"; case kBZip2Compression: return "BZip2"; case kLZ4Compression: return "LZ4"; case kLZ4HCCompression: return "LZ4HC"; case kXpressCompression: return "Xpress"; case kZSTD: return "ZSTD"; case kZSTDNotFinalCompression: return "ZSTDNotFinal"; default: assert(false); return ""; } } // compress_format_version can have two values: // 1 -- decompressed sizes for BZip2 and Zlib are not included in the compressed // block. Also, decompressed sizes for LZ4 are encoded in platform-dependent // way. // 2 -- Zlib, BZip2 and LZ4 encode decompressed size as Varint32 just before the // start of compressed block. Snappy format is the same as version 1. inline bool Snappy_Compress(const CompressionContext& /*ctx*/, const char* input, size_t length, ::std::string* output) { #ifdef SNAPPY output->resize(snappy::MaxCompressedLength(length)); size_t outlen; snappy::RawCompress(input, length, &(*output)[0], &outlen); output->resize(outlen); return true; #else (void)input; (void)length; (void)output; return false; #endif } inline bool Snappy_GetUncompressedLength(const char* input, size_t length, size_t* result) { #ifdef SNAPPY return snappy::GetUncompressedLength(input, length, result); #else (void)input; (void)length; (void)result; return false; #endif } inline bool Snappy_Uncompress(const char* input, size_t length, char* output) { #ifdef SNAPPY return snappy::RawUncompress(input, length, output); #else (void)input; (void)length; (void)output; return false; #endif } namespace compression { // returns size inline size_t PutDecompressedSizeInfo(std::string* output, uint32_t length) { PutVarint32(output, length); return output->size(); } inline bool GetDecompressedSizeInfo(const char** input_data, size_t* input_length, uint32_t* output_len) { auto new_input_data = GetVarint32Ptr(*input_data, *input_data + *input_length, output_len); if (new_input_data == nullptr) { return false; } *input_length -= (new_input_data - *input_data); *input_data = new_input_data; return true; } } // namespace compression // compress_format_version == 1 -- decompressed size is not included in the // block header // compress_format_version == 2 -- decompressed size is included in the block // header in varint32 format // @param compression_dict Data for presetting the compression library's // dictionary. inline bool Zlib_Compress(const CompressionContext& ctx, uint32_t compress_format_version, const char* input, size_t length, ::std::string* output) { #ifdef ZLIB if (length > std::numeric_limits::max()) { // Can't compress more than 4GB return false; } size_t output_header_len = 0; if (compress_format_version == 2) { output_header_len = compression::PutDecompressedSizeInfo( output, static_cast(length)); } // Resize output to be the plain data length. // This may not be big enough if the compression actually expands data. output->resize(output_header_len + length); // The memLevel parameter specifies how much memory should be allocated for // the internal compression state. // memLevel=1 uses minimum memory but is slow and reduces compression ratio. // memLevel=9 uses maximum memory for optimal speed. // The default value is 8. See zconf.h for more details. static const int memLevel = 8; int level; if (ctx.options().level == CompressionOptions::kDefaultCompressionLevel) { level = Z_DEFAULT_COMPRESSION; } else { level = ctx.options().level; } z_stream _stream; memset(&_stream, 0, sizeof(z_stream)); int st = deflateInit2(&_stream, level, Z_DEFLATED, ctx.options().window_bits, memLevel, ctx.options().strategy); if (st != Z_OK) { return false; } if (ctx.dict().size()) { // Initialize the compression library's dictionary st = deflateSetDictionary(&_stream, reinterpret_cast(ctx.dict().data()), static_cast(ctx.dict().size())); if (st != Z_OK) { deflateEnd(&_stream); return false; } } // Compress the input, and put compressed data in output. _stream.next_in = (Bytef*)input; _stream.avail_in = static_cast(length); // Initialize the output size. _stream.avail_out = static_cast(length); _stream.next_out = reinterpret_cast(&(*output)[output_header_len]); bool compressed = false; st = deflate(&_stream, Z_FINISH); if (st == Z_STREAM_END) { compressed = true; output->resize(output->size() - _stream.avail_out); } // The only return value we really care about is Z_STREAM_END. // Z_OK means insufficient output space. This means the compression is // bigger than decompressed size. Just fail the compression in that case. deflateEnd(&_stream); return compressed; #else (void)ctx; (void)compress_format_version; (void)input; (void)length; (void)output; return false; #endif } // compress_format_version == 1 -- decompressed size is not included in the // block header // compress_format_version == 2 -- decompressed size is included in the block // header in varint32 format // @param compression_dict Data for presetting the compression library's // dictionary. inline CacheAllocationPtr Zlib_Uncompress( const UncompressionContext& ctx, const char* input_data, size_t input_length, int* decompress_size, uint32_t compress_format_version, CacheAllocator* allocator = nullptr, int windowBits = -14) { #ifdef ZLIB uint32_t output_len = 0; if (compress_format_version == 2) { if (!compression::GetDecompressedSizeInfo(&input_data, &input_length, &output_len)) { return nullptr; } } else { // Assume the decompressed data size will 5x of compressed size, but round // to the page size size_t proposed_output_len = ((input_length * 5) & (~(4096 - 1))) + 4096; output_len = static_cast( std::min(proposed_output_len, static_cast(std::numeric_limits::max()))); } z_stream _stream; memset(&_stream, 0, sizeof(z_stream)); // For raw inflate, the windowBits should be -8..-15. // If windowBits is bigger than zero, it will use either zlib // header or gzip header. Adding 32 to it will do automatic detection. int st = inflateInit2(&_stream, windowBits > 0 ? windowBits + 32 : windowBits); if (st != Z_OK) { return nullptr; } if (ctx.dict().size()) { // Initialize the compression library's dictionary st = inflateSetDictionary(&_stream, reinterpret_cast(ctx.dict().data()), static_cast(ctx.dict().size())); if (st != Z_OK) { return nullptr; } } _stream.next_in = (Bytef*)input_data; _stream.avail_in = static_cast(input_length); auto output = AllocateBlock(output_len, allocator); _stream.next_out = (Bytef*)output.get(); _stream.avail_out = static_cast(output_len); bool done = false; while (!done) { st = inflate(&_stream, Z_SYNC_FLUSH); switch (st) { case Z_STREAM_END: done = true; break; case Z_OK: { // No output space. Increase the output space by 20%. // We should never run out of output space if // compress_format_version == 2 assert(compress_format_version != 2); size_t old_sz = output_len; uint32_t output_len_delta = output_len / 5; output_len += output_len_delta < 10 ? 10 : output_len_delta; auto tmp = AllocateBlock(output_len, allocator); memcpy(tmp.get(), output.get(), old_sz); output = std::move(tmp); // Set more output. _stream.next_out = (Bytef*)(output.get() + old_sz); _stream.avail_out = static_cast(output_len - old_sz); break; } case Z_BUF_ERROR: default: inflateEnd(&_stream); return nullptr; } } // If we encoded decompressed block size, we should have no bytes left assert(compress_format_version != 2 || _stream.avail_out == 0); *decompress_size = static_cast(output_len - _stream.avail_out); inflateEnd(&_stream); return output; #else (void)ctx; (void)input_data; (void)input_length; (void)decompress_size; (void)compress_format_version; (void)windowBits; return nullptr; #endif } // compress_format_version == 1 -- decompressed size is not included in the // block header // compress_format_version == 2 -- decompressed size is included in the block // header in varint32 format inline bool BZip2_Compress(const CompressionContext& /*ctx*/, uint32_t compress_format_version, const char* input, size_t length, ::std::string* output) { #ifdef BZIP2 if (length > std::numeric_limits::max()) { // Can't compress more than 4GB return false; } size_t output_header_len = 0; if (compress_format_version == 2) { output_header_len = compression::PutDecompressedSizeInfo( output, static_cast(length)); } // Resize output to be the plain data length. // This may not be big enough if the compression actually expands data. output->resize(output_header_len + length); bz_stream _stream; memset(&_stream, 0, sizeof(bz_stream)); // Block size 1 is 100K. // 0 is for silent. // 30 is the default workFactor int st = BZ2_bzCompressInit(&_stream, 1, 0, 30); if (st != BZ_OK) { return false; } // Compress the input, and put compressed data in output. _stream.next_in = (char*)input; _stream.avail_in = static_cast(length); // Initialize the output size. _stream.avail_out = static_cast(length); _stream.next_out = reinterpret_cast(&(*output)[output_header_len]); bool compressed = false; st = BZ2_bzCompress(&_stream, BZ_FINISH); if (st == BZ_STREAM_END) { compressed = true; output->resize(output->size() - _stream.avail_out); } // The only return value we really care about is BZ_STREAM_END. // BZ_FINISH_OK means insufficient output space. This means the compression // is bigger than decompressed size. Just fail the compression in that case. BZ2_bzCompressEnd(&_stream); return compressed; #else (void)compress_format_version; (void)input; (void)length; (void)output; return false; #endif } // compress_format_version == 1 -- decompressed size is not included in the // block header // compress_format_version == 2 -- decompressed size is included in the block // header in varint32 format inline CacheAllocationPtr BZip2_Uncompress( const char* input_data, size_t input_length, int* decompress_size, uint32_t compress_format_version, CacheAllocator* allocator = nullptr) { #ifdef BZIP2 uint32_t output_len = 0; if (compress_format_version == 2) { if (!compression::GetDecompressedSizeInfo(&input_data, &input_length, &output_len)) { return nullptr; } } else { // Assume the decompressed data size will 5x of compressed size, but round // to the next page size size_t proposed_output_len = ((input_length * 5) & (~(4096 - 1))) + 4096; output_len = static_cast( std::min(proposed_output_len, static_cast(std::numeric_limits::max()))); } bz_stream _stream; memset(&_stream, 0, sizeof(bz_stream)); int st = BZ2_bzDecompressInit(&_stream, 0, 0); if (st != BZ_OK) { return nullptr; } _stream.next_in = (char*)input_data; _stream.avail_in = static_cast(input_length); auto output = AllocateBlock(output_len, allocator); _stream.next_out = (char*)output.get(); _stream.avail_out = static_cast(output_len); bool done = false; while (!done) { st = BZ2_bzDecompress(&_stream); switch (st) { case BZ_STREAM_END: done = true; break; case BZ_OK: { // No output space. Increase the output space by 20%. // We should never run out of output space if // compress_format_version == 2 assert(compress_format_version != 2); uint32_t old_sz = output_len; output_len = output_len * 1.2; auto tmp = AllocateBlock(output_len, allocator); memcpy(tmp.get(), output.get(), old_sz); output = std::move(tmp); // Set more output. _stream.next_out = (char*)(output.get() + old_sz); _stream.avail_out = static_cast(output_len - old_sz); break; } default: BZ2_bzDecompressEnd(&_stream); return nullptr; } } // If we encoded decompressed block size, we should have no bytes left assert(compress_format_version != 2 || _stream.avail_out == 0); *decompress_size = static_cast(output_len - _stream.avail_out); BZ2_bzDecompressEnd(&_stream); return output; #else (void)input_data; (void)input_length; (void)decompress_size; (void)compress_format_version; return nullptr; #endif } // compress_format_version == 1 -- decompressed size is included in the // block header using memcpy, which makes database non-portable) // compress_format_version == 2 -- decompressed size is included in the block // header in varint32 format // @param compression_dict Data for presetting the compression library's // dictionary. inline bool LZ4_Compress(const CompressionContext& ctx, uint32_t compress_format_version, const char* input, size_t length, ::std::string* output) { #ifdef LZ4 if (length > std::numeric_limits::max()) { // Can't compress more than 4GB return false; } size_t output_header_len = 0; if (compress_format_version == 2) { // new encoding, using varint32 to store size information output_header_len = compression::PutDecompressedSizeInfo( output, static_cast(length)); } else { // legacy encoding, which is not really portable (depends on big/little // endianness) output_header_len = 8; output->resize(output_header_len); char* p = const_cast(output->c_str()); memcpy(p, &length, sizeof(length)); } int compress_bound = LZ4_compressBound(static_cast(length)); output->resize(static_cast(output_header_len + compress_bound)); int outlen; #if LZ4_VERSION_NUMBER >= 10400 // r124+ LZ4_stream_t* stream = LZ4_createStream(); if (ctx.dict().size()) { LZ4_loadDict(stream, ctx.dict().data(), static_cast(ctx.dict().size())); } #if LZ4_VERSION_NUMBER >= 10700 // r129+ outlen = LZ4_compress_fast_continue(stream, input, &(*output)[output_header_len], static_cast(length), compress_bound, 1); #else // up to r128 outlen = LZ4_compress_limitedOutput_continue( stream, input, &(*output)[output_header_len], static_cast(length), compress_bound); #endif LZ4_freeStream(stream); #else // up to r123 outlen = LZ4_compress_limitedOutput(input, &(*output)[output_header_len], static_cast(length), compress_bound); #endif // LZ4_VERSION_NUMBER >= 10400 if (outlen == 0) { return false; } output->resize(static_cast(output_header_len + outlen)); return true; #else // LZ4 (void)ctx; (void)compress_format_version; (void)input; (void)length; (void)output; return false; #endif } // compress_format_version == 1 -- decompressed size is included in the // block header using memcpy, which makes database non-portable) // compress_format_version == 2 -- decompressed size is included in the block // header in varint32 format // @param compression_dict Data for presetting the compression library's // dictionary. inline CacheAllocationPtr LZ4_Uncompress(const UncompressionContext& ctx, const char* input_data, size_t input_length, int* decompress_size, uint32_t compress_format_version, CacheAllocator* allocator = nullptr) { #ifdef LZ4 uint32_t output_len = 0; if (compress_format_version == 2) { // new encoding, using varint32 to store size information if (!compression::GetDecompressedSizeInfo(&input_data, &input_length, &output_len)) { return nullptr; } } else { // legacy encoding, which is not really portable (depends on big/little // endianness) if (input_length < 8) { return nullptr; } memcpy(&output_len, input_data, sizeof(output_len)); input_length -= 8; input_data += 8; } auto output = AllocateBlock(output_len, allocator); #if LZ4_VERSION_NUMBER >= 10400 // r124+ LZ4_streamDecode_t* stream = LZ4_createStreamDecode(); if (ctx.dict().size()) { LZ4_setStreamDecode(stream, ctx.dict().data(), static_cast(ctx.dict().size())); } *decompress_size = LZ4_decompress_safe_continue( stream, input_data, output.get(), static_cast(input_length), static_cast(output_len)); LZ4_freeStreamDecode(stream); #else // up to r123 *decompress_size = LZ4_decompress_safe(input_data, output.get(), static_cast(input_length), static_cast(output_len)); #endif // LZ4_VERSION_NUMBER >= 10400 if (*decompress_size < 0) { return nullptr; } assert(*decompress_size == static_cast(output_len)); return output; #else // LZ4 (void)ctx; (void)input_data; (void)input_length; (void)decompress_size; (void)compress_format_version; (void)allocator; return nullptr; #endif } // compress_format_version == 1 -- decompressed size is included in the // block header using memcpy, which makes database non-portable) // compress_format_version == 2 -- decompressed size is included in the block // header in varint32 format // @param compression_dict Data for presetting the compression library's // dictionary. inline bool LZ4HC_Compress(const CompressionContext& ctx, uint32_t compress_format_version, const char* input, size_t length, ::std::string* output) { #ifdef LZ4 if (length > std::numeric_limits::max()) { // Can't compress more than 4GB return false; } size_t output_header_len = 0; if (compress_format_version == 2) { // new encoding, using varint32 to store size information output_header_len = compression::PutDecompressedSizeInfo( output, static_cast(length)); } else { // legacy encoding, which is not really portable (depends on big/little // endianness) output_header_len = 8; output->resize(output_header_len); char* p = const_cast(output->c_str()); memcpy(p, &length, sizeof(length)); } int compress_bound = LZ4_compressBound(static_cast(length)); output->resize(static_cast(output_header_len + compress_bound)); int outlen; int level; if (ctx.options().level == CompressionOptions::kDefaultCompressionLevel) { level = 0; // lz4hc.h says any value < 1 will be sanitized to default } else { level = ctx.options().level; } #if LZ4_VERSION_NUMBER >= 10400 // r124+ LZ4_streamHC_t* stream = LZ4_createStreamHC(); LZ4_resetStreamHC(stream, level); const char* compression_dict_data = ctx.dict().size() > 0 ? ctx.dict().data() : nullptr; size_t compression_dict_size = ctx.dict().size(); LZ4_loadDictHC(stream, compression_dict_data, static_cast(compression_dict_size)); #if LZ4_VERSION_NUMBER >= 10700 // r129+ outlen = LZ4_compress_HC_continue(stream, input, &(*output)[output_header_len], static_cast(length), compress_bound); #else // r124-r128 outlen = LZ4_compressHC_limitedOutput_continue( stream, input, &(*output)[output_header_len], static_cast(length), compress_bound); #endif // LZ4_VERSION_NUMBER >= 10700 LZ4_freeStreamHC(stream); #elif LZ4_VERSION_MAJOR // r113-r123 outlen = LZ4_compressHC2_limitedOutput(input, &(*output)[output_header_len], static_cast(length), compress_bound, level); #else // up to r112 outlen = LZ4_compressHC_limitedOutput(input, &(*output)[output_header_len], static_cast(length), compress_bound); #endif // LZ4_VERSION_NUMBER >= 10400 if (outlen == 0) { return false; } output->resize(static_cast(output_header_len + outlen)); return true; #else // LZ4 (void)ctx; (void)compress_format_version; (void)input; (void)length; (void)output; return false; #endif } #ifdef XPRESS inline bool XPRESS_Compress(const char* input, size_t length, std::string* output) { return port::xpress::Compress(input, length, output); } #else inline bool XPRESS_Compress(const char* /*input*/, size_t /*length*/, std::string* /*output*/) { return false; } #endif #ifdef XPRESS inline char* XPRESS_Uncompress(const char* input_data, size_t input_length, int* decompress_size) { return port::xpress::Decompress(input_data, input_length, decompress_size); } #else inline char* XPRESS_Uncompress(const char* /*input_data*/, size_t /*input_length*/, int* /*decompress_size*/) { return nullptr; } #endif // @param compression_dict Data for presetting the compression library's // dictionary. inline bool ZSTD_Compress(const CompressionContext& ctx, const char* input, size_t length, ::std::string* output) { #ifdef ZSTD if (length > std::numeric_limits::max()) { // Can't compress more than 4GB return false; } size_t output_header_len = compression::PutDecompressedSizeInfo( output, static_cast(length)); size_t compressBound = ZSTD_compressBound(length); output->resize(static_cast(output_header_len + compressBound)); size_t outlen = 0; int level; if (ctx.options().level == CompressionOptions::kDefaultCompressionLevel) { // 3 is the value of ZSTD_CLEVEL_DEFAULT (not exposed publicly), see // https://github.com/facebook/zstd/issues/1148 level = 3; } else { level = ctx.options().level; } #if ZSTD_VERSION_NUMBER >= 500 // v0.5.0+ ZSTD_CCtx* context = ctx.ZSTDPreallocCtx(); assert(context != nullptr); outlen = ZSTD_compress_usingDict(context, &(*output)[output_header_len], compressBound, input, length, ctx.dict().data(), ctx.dict().size(), level); #else // up to v0.4.x outlen = ZSTD_compress(&(*output)[output_header_len], compressBound, input, length, level); #endif // ZSTD_VERSION_NUMBER >= 500 if (outlen == 0) { return false; } output->resize(output_header_len + outlen); return true; #else // ZSTD (void)ctx; (void)input; (void)length; (void)output; return false; #endif } // @param compression_dict Data for presetting the compression library's // dictionary. inline CacheAllocationPtr ZSTD_Uncompress(const UncompressionContext& ctx, const char* input_data, size_t input_length, int* decompress_size, CacheAllocator* allocator = nullptr) { #ifdef ZSTD uint32_t output_len = 0; if (!compression::GetDecompressedSizeInfo(&input_data, &input_length, &output_len)) { return nullptr; } auto output = AllocateBlock(output_len, allocator); size_t actual_output_length; #if ZSTD_VERSION_NUMBER >= 500 // v0.5.0+ ZSTD_DCtx* context = ctx.GetZSTDContext(); assert(context != nullptr); actual_output_length = ZSTD_decompress_usingDict( context, output.get(), output_len, input_data, input_length, ctx.dict().data(), ctx.dict().size()); #else // up to v0.4.x actual_output_length = ZSTD_decompress(output.get(), output_len, input_data, input_length); #endif // ZSTD_VERSION_NUMBER >= 500 assert(actual_output_length == output_len); *decompress_size = static_cast(actual_output_length); return output; #else // ZSTD (void)ctx; (void)input_data; (void)input_length; (void)decompress_size; (void)allocator; return nullptr; #endif } inline std::string ZSTD_TrainDictionary(const std::string& samples, const std::vector& sample_lens, size_t max_dict_bytes) { // Dictionary trainer is available since v0.6.1 for static linking, but not // available for dynamic linking until v1.1.3. For now we enable the feature // in v1.1.3+ only. #if ZSTD_VERSION_NUMBER >= 10103 // v1.1.3+ std::string dict_data(max_dict_bytes, '\0'); size_t dict_len = ZDICT_trainFromBuffer( &dict_data[0], max_dict_bytes, &samples[0], &sample_lens[0], static_cast(sample_lens.size())); if (ZDICT_isError(dict_len)) { return ""; } assert(dict_len <= max_dict_bytes); dict_data.resize(dict_len); return dict_data; #else // up to v1.1.2 assert(false); (void)samples; (void)sample_lens; (void)max_dict_bytes; return ""; #endif // ZSTD_VERSION_NUMBER >= 10103 } inline std::string ZSTD_TrainDictionary(const std::string& samples, size_t sample_len_shift, size_t max_dict_bytes) { // Dictionary trainer is available since v0.6.1, but ZSTD was marked stable // only since v0.8.0. For now we enable the feature in stable versions only. #if ZSTD_VERSION_NUMBER >= 10103 // v1.1.3+ // skips potential partial sample at the end of "samples" size_t num_samples = samples.size() >> sample_len_shift; std::vector sample_lens(num_samples, size_t(1) << sample_len_shift); return ZSTD_TrainDictionary(samples, sample_lens, max_dict_bytes); #else // up to v1.1.2 assert(false); (void)samples; (void)sample_len_shift; (void)max_dict_bytes; return ""; #endif // ZSTD_VERSION_NUMBER >= 10103 } } // namespace rocksdb