// 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. #include "db/log_reader.h" #include #include "file/sequence_file_reader.h" #include "port/lang.h" #include "rocksdb/env.h" #include "test_util/sync_point.h" #include "util/coding.h" #include "util/crc32c.h" namespace ROCKSDB_NAMESPACE { namespace log { Reader::Reporter::~Reporter() = default; Reader::Reader(std::shared_ptr info_log, std::unique_ptr&& _file, Reporter* reporter, bool checksum, uint64_t log_num) : info_log_(info_log), file_(std::move(_file)), reporter_(reporter), checksum_(checksum), backing_store_(new char[kBlockSize]), buffer_(), eof_(false), read_error_(false), eof_offset_(0), last_record_offset_(0), end_of_buffer_offset_(0), log_number_(log_num), recycled_(false), first_record_read_(false), compression_type_(kNoCompression), compression_type_record_read_(false), uncompress_(nullptr), hash_state_(nullptr), uncompress_hash_state_(nullptr){}; Reader::~Reader() { delete[] backing_store_; if (uncompress_) { delete uncompress_; } if (hash_state_) { XXH3_freeState(hash_state_); } if (uncompress_hash_state_) { XXH3_freeState(uncompress_hash_state_); } } // For kAbsoluteConsistency, on clean shutdown we don't expect any error // in the log files. For other modes, we can ignore only incomplete records // in the last log file, which are presumably due to a write in progress // during restart (or from log recycling). // // TODO krad: Evaluate if we need to move to a more strict mode where we // restrict the inconsistency to only the last log bool Reader::ReadRecord(Slice* record, std::string* scratch, WALRecoveryMode wal_recovery_mode, uint64_t* record_checksum) { scratch->clear(); record->clear(); if (record_checksum != nullptr) { if (hash_state_ == nullptr) { hash_state_ = XXH3_createState(); } XXH3_64bits_reset(hash_state_); } if (uncompress_) { uncompress_->Reset(); } bool in_fragmented_record = false; // Record offset of the logical record that we're reading // 0 is a dummy value to make compilers happy uint64_t prospective_record_offset = 0; Slice fragment; while (true) { uint64_t physical_record_offset = end_of_buffer_offset_ - buffer_.size(); size_t drop_size = 0; const unsigned int record_type = ReadPhysicalRecord(&fragment, &drop_size, record_checksum); switch (record_type) { case kFullType: case kRecyclableFullType: if (in_fragmented_record && !scratch->empty()) { // Handle bug in earlier versions of log::Writer where // it could emit an empty kFirstType record at the tail end // of a block followed by a kFullType or kFirstType record // at the beginning of the next block. ReportCorruption(scratch->size(), "partial record without end(1)"); } // No need to compute record_checksum since the record // consists of a single fragment and the checksum is computed // in ReadPhysicalRecord() if WAL compression is enabled if (record_checksum != nullptr && uncompress_ == nullptr) { // No need to stream since the record is a single fragment *record_checksum = XXH3_64bits(fragment.data(), fragment.size()); } prospective_record_offset = physical_record_offset; scratch->clear(); *record = fragment; last_record_offset_ = prospective_record_offset; first_record_read_ = true; return true; case kFirstType: case kRecyclableFirstType: if (in_fragmented_record && !scratch->empty()) { // Handle bug in earlier versions of log::Writer where // it could emit an empty kFirstType record at the tail end // of a block followed by a kFullType or kFirstType record // at the beginning of the next block. ReportCorruption(scratch->size(), "partial record without end(2)"); XXH3_64bits_reset(hash_state_); } if (record_checksum != nullptr) { XXH3_64bits_update(hash_state_, fragment.data(), fragment.size()); } prospective_record_offset = physical_record_offset; scratch->assign(fragment.data(), fragment.size()); in_fragmented_record = true; break; case kMiddleType: case kRecyclableMiddleType: if (!in_fragmented_record) { ReportCorruption(fragment.size(), "missing start of fragmented record(1)"); } else { if (record_checksum != nullptr) { XXH3_64bits_update(hash_state_, fragment.data(), fragment.size()); } scratch->append(fragment.data(), fragment.size()); } break; case kLastType: case kRecyclableLastType: if (!in_fragmented_record) { ReportCorruption(fragment.size(), "missing start of fragmented record(2)"); } else { if (record_checksum != nullptr) { XXH3_64bits_update(hash_state_, fragment.data(), fragment.size()); *record_checksum = XXH3_64bits_digest(hash_state_); } scratch->append(fragment.data(), fragment.size()); *record = Slice(*scratch); last_record_offset_ = prospective_record_offset; first_record_read_ = true; return true; } break; case kSetCompressionType: { if (compression_type_record_read_) { ReportCorruption(fragment.size(), "read multiple SetCompressionType records"); } if (first_record_read_) { ReportCorruption(fragment.size(), "SetCompressionType not the first record"); } prospective_record_offset = physical_record_offset; scratch->clear(); last_record_offset_ = prospective_record_offset; CompressionTypeRecord compression_record(kNoCompression); Status s = compression_record.DecodeFrom(&fragment); if (!s.ok()) { ReportCorruption(fragment.size(), "could not decode SetCompressionType record"); } else { InitCompression(compression_record); } break; } case kUserDefinedTimestampSizeType: case kRecyclableUserDefinedTimestampSizeType: { if (in_fragmented_record && !scratch->empty()) { ReportCorruption( scratch->size(), "user-defined timestamp size record interspersed partial record"); } prospective_record_offset = physical_record_offset; scratch->clear(); last_record_offset_ = prospective_record_offset; UserDefinedTimestampSizeRecord ts_record; Status s = ts_record.DecodeFrom(&fragment); if (!s.ok()) { ReportCorruption( fragment.size(), "could not decode user-defined timestamp size record"); } else { s = UpdateRecordedTimestampSize( ts_record.GetUserDefinedTimestampSize()); if (!s.ok()) { ReportCorruption(fragment.size(), s.getState()); } } break; } case kBadHeader: if (wal_recovery_mode == WALRecoveryMode::kAbsoluteConsistency || wal_recovery_mode == WALRecoveryMode::kPointInTimeRecovery) { // In clean shutdown we don't expect any error in the log files. // In point-in-time recovery an incomplete record at the end could // produce a hole in the recovered data. Report an error here, which // higher layers can choose to ignore when it's provable there is no // hole. ReportCorruption(drop_size, "truncated header"); } FALLTHROUGH_INTENDED; case kEof: if (in_fragmented_record) { if (wal_recovery_mode == WALRecoveryMode::kAbsoluteConsistency || wal_recovery_mode == WALRecoveryMode::kPointInTimeRecovery) { // In clean shutdown we don't expect any error in the log files. // In point-in-time recovery an incomplete record at the end could // produce a hole in the recovered data. Report an error here, which // higher layers can choose to ignore when it's provable there is no // hole. ReportCorruption(scratch->size(), "error reading trailing data"); } // This can be caused by the writer dying immediately after // writing a physical record but before completing the next; don't // treat it as a corruption, just ignore the entire logical record. scratch->clear(); } return false; case kOldRecord: if (wal_recovery_mode != WALRecoveryMode::kSkipAnyCorruptedRecords) { // Treat a record from a previous instance of the log as EOF. if (in_fragmented_record) { if (wal_recovery_mode == WALRecoveryMode::kAbsoluteConsistency || wal_recovery_mode == WALRecoveryMode::kPointInTimeRecovery) { // In clean shutdown we don't expect any error in the log files. // In point-in-time recovery an incomplete record at the end could // produce a hole in the recovered data. Report an error here, // which higher layers can choose to ignore when it's provable // there is no hole. ReportCorruption(scratch->size(), "error reading trailing data"); } // This can be caused by the writer dying immediately after // writing a physical record but before completing the next; don't // treat it as a corruption, just ignore the entire logical record. scratch->clear(); } return false; } FALLTHROUGH_INTENDED; case kBadRecord: if (in_fragmented_record) { ReportCorruption(scratch->size(), "error in middle of record"); in_fragmented_record = false; scratch->clear(); } break; case kBadRecordLen: if (eof_) { if (wal_recovery_mode == WALRecoveryMode::kAbsoluteConsistency || wal_recovery_mode == WALRecoveryMode::kPointInTimeRecovery) { // In clean shutdown we don't expect any error in the log files. // In point-in-time recovery an incomplete record at the end could // produce a hole in the recovered data. Report an error here, which // higher layers can choose to ignore when it's provable there is no // hole. ReportCorruption(drop_size, "truncated record body"); } return false; } FALLTHROUGH_INTENDED; case kBadRecordChecksum: if (recycled_ && wal_recovery_mode == WALRecoveryMode::kTolerateCorruptedTailRecords) { scratch->clear(); return false; } if (record_type == kBadRecordLen) { ReportCorruption(drop_size, "bad record length"); } else { ReportCorruption(drop_size, "checksum mismatch"); } if (in_fragmented_record) { ReportCorruption(scratch->size(), "error in middle of record"); in_fragmented_record = false; scratch->clear(); } break; default: { char buf[40]; snprintf(buf, sizeof(buf), "unknown record type %u", record_type); ReportCorruption( (fragment.size() + (in_fragmented_record ? scratch->size() : 0)), buf); in_fragmented_record = false; scratch->clear(); break; } } } return false; } uint64_t Reader::LastRecordOffset() { return last_record_offset_; } uint64_t Reader::LastRecordEnd() { return end_of_buffer_offset_ - buffer_.size(); } void Reader::UnmarkEOF() { if (read_error_) { return; } eof_ = false; if (eof_offset_ == 0) { return; } UnmarkEOFInternal(); } void Reader::UnmarkEOFInternal() { // If the EOF was in the middle of a block (a partial block was read) we have // to read the rest of the block as ReadPhysicalRecord can only read full // blocks and expects the file position indicator to be aligned to the start // of a block. // // consumed_bytes + buffer_size() + remaining == kBlockSize size_t consumed_bytes = eof_offset_ - buffer_.size(); size_t remaining = kBlockSize - eof_offset_; // backing_store_ is used to concatenate what is left in buffer_ and // the remainder of the block. If buffer_ already uses backing_store_, // we just append the new data. if (buffer_.data() != backing_store_ + consumed_bytes) { // Buffer_ does not use backing_store_ for storage. // Copy what is left in buffer_ to backing_store. memmove(backing_store_ + consumed_bytes, buffer_.data(), buffer_.size()); } Slice read_buffer; // TODO: rate limit log reader with approriate priority. // TODO: avoid overcharging rate limiter: // Note that the Read here might overcharge SequentialFileReader's internal // rate limiter if priority is not IO_TOTAL, e.g., when there is not enough // content left until EOF to read. Status status = file_->Read(remaining, &read_buffer, backing_store_ + eof_offset_, Env::IO_TOTAL /* rate_limiter_priority */); size_t added = read_buffer.size(); end_of_buffer_offset_ += added; if (!status.ok()) { if (added > 0) { ReportDrop(added, status); } read_error_ = true; return; } if (read_buffer.data() != backing_store_ + eof_offset_) { // Read did not write to backing_store_ memmove(backing_store_ + eof_offset_, read_buffer.data(), read_buffer.size()); } buffer_ = Slice(backing_store_ + consumed_bytes, eof_offset_ + added - consumed_bytes); if (added < remaining) { eof_ = true; eof_offset_ += added; } else { eof_offset_ = 0; } } void Reader::ReportCorruption(size_t bytes, const char* reason) { ReportDrop(bytes, Status::Corruption(reason)); } void Reader::ReportDrop(size_t bytes, const Status& reason) { if (reporter_ != nullptr) { reporter_->Corruption(bytes, reason); } } bool Reader::ReadMore(size_t* drop_size, int* error) { if (!eof_ && !read_error_) { // Last read was a full read, so this is a trailer to skip buffer_.clear(); // TODO: rate limit log reader with approriate priority. // TODO: avoid overcharging rate limiter: // Note that the Read here might overcharge SequentialFileReader's internal // rate limiter if priority is not IO_TOTAL, e.g., when there is not enough // content left until EOF to read. Status status = file_->Read(kBlockSize, &buffer_, backing_store_, Env::IO_TOTAL /* rate_limiter_priority */); TEST_SYNC_POINT_CALLBACK("LogReader::ReadMore:AfterReadFile", &status); end_of_buffer_offset_ += buffer_.size(); if (!status.ok()) { buffer_.clear(); ReportDrop(kBlockSize, status); read_error_ = true; *error = kEof; return false; } else if (buffer_.size() < static_cast(kBlockSize)) { eof_ = true; eof_offset_ = buffer_.size(); } return true; } else { // Note that if buffer_ is non-empty, we have a truncated header at the // end of the file, which can be caused by the writer crashing in the // middle of writing the header. Unless explicitly requested we don't // considering this an error, just report EOF. if (buffer_.size()) { *drop_size = buffer_.size(); buffer_.clear(); *error = kBadHeader; return false; } buffer_.clear(); *error = kEof; return false; } } unsigned int Reader::ReadPhysicalRecord(Slice* result, size_t* drop_size, uint64_t* fragment_checksum) { while (true) { // We need at least the minimum header size if (buffer_.size() < static_cast(kHeaderSize)) { // the default value of r is meaningless because ReadMore will overwrite // it if it returns false; in case it returns true, the return value will // not be used anyway int r = kEof; if (!ReadMore(drop_size, &r)) { return r; } continue; } // Parse the header const char* header = buffer_.data(); const uint32_t a = static_cast(header[4]) & 0xff; const uint32_t b = static_cast(header[5]) & 0xff; const unsigned int type = header[6]; const uint32_t length = a | (b << 8); int header_size = kHeaderSize; const bool is_recyclable_type = ((type >= kRecyclableFullType && type <= kRecyclableLastType) || type == kRecyclableUserDefinedTimestampSizeType); if (is_recyclable_type) { header_size = kRecyclableHeaderSize; if (end_of_buffer_offset_ - buffer_.size() == 0) { recycled_ = true; } // We need enough for the larger header if (buffer_.size() < static_cast(kRecyclableHeaderSize)) { int r = kEof; if (!ReadMore(drop_size, &r)) { return r; } continue; } } if (header_size + length > buffer_.size()) { assert(buffer_.size() >= static_cast(header_size)); *drop_size = buffer_.size(); buffer_.clear(); // If the end of the read has been reached without seeing // `header_size + length` bytes of payload, report a corruption. The // higher layers can decide how to handle it based on the recovery mode, // whether this occurred at EOF, whether this is the final WAL, etc. return kBadRecordLen; } if (is_recyclable_type) { const uint32_t log_num = DecodeFixed32(header + 7); if (log_num != log_number_) { buffer_.remove_prefix(header_size + length); return kOldRecord; } } if (type == kZeroType && length == 0) { // Skip zero length record without reporting any drops since // such records are produced by the mmap based writing code in // env_posix.cc that preallocates file regions. // NOTE: this should never happen in DB written by new RocksDB versions, // since we turn off mmap writes to manifest and log files buffer_.clear(); return kBadRecord; } // Check crc if (checksum_) { uint32_t expected_crc = crc32c::Unmask(DecodeFixed32(header)); uint32_t actual_crc = crc32c::Value(header + 6, length + header_size - 6); if (actual_crc != expected_crc) { // Drop the rest of the buffer since "length" itself may have // been corrupted and if we trust it, we could find some // fragment of a real log record that just happens to look // like a valid log record. *drop_size = buffer_.size(); buffer_.clear(); return kBadRecordChecksum; } } buffer_.remove_prefix(header_size + length); if (!uncompress_ || type == kSetCompressionType || type == kUserDefinedTimestampSizeType || type == kRecyclableUserDefinedTimestampSizeType) { *result = Slice(header + header_size, length); return type; } else { // Uncompress compressed records uncompressed_record_.clear(); if (fragment_checksum != nullptr) { if (uncompress_hash_state_ == nullptr) { uncompress_hash_state_ = XXH3_createState(); } XXH3_64bits_reset(uncompress_hash_state_); } size_t uncompressed_size = 0; int remaining = 0; const char* input = header + header_size; do { remaining = uncompress_->Uncompress( input, length, uncompressed_buffer_.get(), &uncompressed_size); input = nullptr; if (remaining < 0) { buffer_.clear(); return kBadRecord; } if (uncompressed_size > 0) { if (fragment_checksum != nullptr) { XXH3_64bits_update(uncompress_hash_state_, uncompressed_buffer_.get(), uncompressed_size); } uncompressed_record_.append(uncompressed_buffer_.get(), uncompressed_size); } } while (remaining > 0 || uncompressed_size == kBlockSize); if (fragment_checksum != nullptr) { // We can remove this check by updating hash_state_ directly, // but that requires resetting hash_state_ for full and first types // for edge cases like consecutive fist type records. // Leaving the check as is since it is cleaner and can revert to the // above approach if it causes performance impact. *fragment_checksum = XXH3_64bits_digest(uncompress_hash_state_); uint64_t actual_checksum = XXH3_64bits(uncompressed_record_.data(), uncompressed_record_.size()); if (*fragment_checksum != actual_checksum) { // uncompressed_record_ contains bad content that does not match // actual decompressed content return kBadRecord; } } *result = Slice(uncompressed_record_); return type; } } } // Initialize uncompress related fields void Reader::InitCompression(const CompressionTypeRecord& compression_record) { compression_type_ = compression_record.GetCompressionType(); compression_type_record_read_ = true; constexpr uint32_t compression_format_version = 2; uncompress_ = StreamingUncompress::Create( compression_type_, compression_format_version, kBlockSize); assert(uncompress_ != nullptr); uncompressed_buffer_ = std::unique_ptr(new char[kBlockSize]); assert(uncompressed_buffer_); } Status Reader::UpdateRecordedTimestampSize( const std::vector>& cf_to_ts_sz) { for (const auto& [cf, ts_sz] : cf_to_ts_sz) { // Zero user-defined timestamp size are not recorded. if (ts_sz == 0) { return Status::Corruption( "User-defined timestamp size record contains zero timestamp size."); } // The user-defined timestamp size record for a column family should not be // updated in the same log file. if (recorded_cf_to_ts_sz_.count(cf) != 0) { return Status::Corruption( "User-defined timestamp size record contains update to " "recorded column family."); } recorded_cf_to_ts_sz_.insert(std::make_pair(cf, ts_sz)); } return Status::OK(); } bool FragmentBufferedReader::ReadRecord(Slice* record, std::string* scratch, WALRecoveryMode /*unused*/, uint64_t* /* checksum */) { assert(record != nullptr); assert(scratch != nullptr); record->clear(); scratch->clear(); if (uncompress_) { uncompress_->Reset(); } uint64_t prospective_record_offset = 0; uint64_t physical_record_offset = end_of_buffer_offset_ - buffer_.size(); size_t drop_size = 0; unsigned int fragment_type_or_err = 0; // Initialize to make compiler happy Slice fragment; while (TryReadFragment(&fragment, &drop_size, &fragment_type_or_err)) { switch (fragment_type_or_err) { case kFullType: case kRecyclableFullType: if (in_fragmented_record_ && !fragments_.empty()) { ReportCorruption(fragments_.size(), "partial record without end(1)"); } fragments_.clear(); *record = fragment; prospective_record_offset = physical_record_offset; last_record_offset_ = prospective_record_offset; first_record_read_ = true; in_fragmented_record_ = false; return true; case kFirstType: case kRecyclableFirstType: if (in_fragmented_record_ || !fragments_.empty()) { ReportCorruption(fragments_.size(), "partial record without end(2)"); } prospective_record_offset = physical_record_offset; fragments_.assign(fragment.data(), fragment.size()); in_fragmented_record_ = true; break; case kMiddleType: case kRecyclableMiddleType: if (!in_fragmented_record_) { ReportCorruption(fragment.size(), "missing start of fragmented record(1)"); } else { fragments_.append(fragment.data(), fragment.size()); } break; case kLastType: case kRecyclableLastType: if (!in_fragmented_record_) { ReportCorruption(fragment.size(), "missing start of fragmented record(2)"); } else { fragments_.append(fragment.data(), fragment.size()); scratch->assign(fragments_.data(), fragments_.size()); fragments_.clear(); *record = Slice(*scratch); last_record_offset_ = prospective_record_offset; first_record_read_ = true; in_fragmented_record_ = false; return true; } break; case kSetCompressionType: { if (compression_type_record_read_) { ReportCorruption(fragment.size(), "read multiple SetCompressionType records"); } if (first_record_read_) { ReportCorruption(fragment.size(), "SetCompressionType not the first record"); } fragments_.clear(); prospective_record_offset = physical_record_offset; last_record_offset_ = prospective_record_offset; in_fragmented_record_ = false; CompressionTypeRecord compression_record(kNoCompression); Status s = compression_record.DecodeFrom(&fragment); if (!s.ok()) { ReportCorruption(fragment.size(), "could not decode SetCompressionType record"); } else { InitCompression(compression_record); } break; } case kUserDefinedTimestampSizeType: case kRecyclableUserDefinedTimestampSizeType: { if (in_fragmented_record_ && !scratch->empty()) { ReportCorruption( scratch->size(), "user-defined timestamp size record interspersed partial record"); } fragments_.clear(); prospective_record_offset = physical_record_offset; last_record_offset_ = prospective_record_offset; in_fragmented_record_ = false; UserDefinedTimestampSizeRecord ts_record; Status s = ts_record.DecodeFrom(&fragment); if (!s.ok()) { ReportCorruption( fragment.size(), "could not decode user-defined timestamp size record"); } else { s = UpdateRecordedTimestampSize( ts_record.GetUserDefinedTimestampSize()); if (!s.ok()) { ReportCorruption(fragment.size(), s.getState()); } } break; } case kBadHeader: case kBadRecord: case kEof: case kOldRecord: if (in_fragmented_record_) { ReportCorruption(fragments_.size(), "error in middle of record"); in_fragmented_record_ = false; fragments_.clear(); } break; case kBadRecordChecksum: if (recycled_) { fragments_.clear(); return false; } ReportCorruption(drop_size, "checksum mismatch"); if (in_fragmented_record_) { ReportCorruption(fragments_.size(), "error in middle of record"); in_fragmented_record_ = false; fragments_.clear(); } break; default: { char buf[40]; snprintf(buf, sizeof(buf), "unknown record type %u", fragment_type_or_err); ReportCorruption( fragment.size() + (in_fragmented_record_ ? fragments_.size() : 0), buf); in_fragmented_record_ = false; fragments_.clear(); break; } } } return false; } void FragmentBufferedReader::UnmarkEOF() { if (read_error_) { return; } eof_ = false; UnmarkEOFInternal(); } bool FragmentBufferedReader::TryReadMore(size_t* drop_size, int* error) { if (!eof_ && !read_error_) { // Last read was a full read, so this is a trailer to skip buffer_.clear(); // TODO: rate limit log reader with approriate priority. // TODO: avoid overcharging rate limiter: // Note that the Read here might overcharge SequentialFileReader's internal // rate limiter if priority is not IO_TOTAL, e.g., when there is not enough // content left until EOF to read. Status status = file_->Read(kBlockSize, &buffer_, backing_store_, Env::IO_TOTAL /* rate_limiter_priority */); end_of_buffer_offset_ += buffer_.size(); if (!status.ok()) { buffer_.clear(); ReportDrop(kBlockSize, status); read_error_ = true; *error = kEof; return false; } else if (buffer_.size() < static_cast(kBlockSize)) { eof_ = true; eof_offset_ = buffer_.size(); TEST_SYNC_POINT_CALLBACK( "FragmentBufferedLogReader::TryReadMore:FirstEOF", nullptr); } return true; } else if (!read_error_) { UnmarkEOF(); } if (!read_error_) { return true; } *error = kEof; *drop_size = buffer_.size(); if (buffer_.size() > 0) { *error = kBadHeader; } buffer_.clear(); return false; } // return true if the caller should process the fragment_type_or_err. bool FragmentBufferedReader::TryReadFragment( Slice* fragment, size_t* drop_size, unsigned int* fragment_type_or_err) { assert(fragment != nullptr); assert(drop_size != nullptr); assert(fragment_type_or_err != nullptr); while (buffer_.size() < static_cast(kHeaderSize)) { size_t old_size = buffer_.size(); int error = kEof; if (!TryReadMore(drop_size, &error)) { *fragment_type_or_err = error; return false; } else if (old_size == buffer_.size()) { return false; } } const char* header = buffer_.data(); const uint32_t a = static_cast(header[4]) & 0xff; const uint32_t b = static_cast(header[5]) & 0xff; const unsigned int type = header[6]; const uint32_t length = a | (b << 8); int header_size = kHeaderSize; if ((type >= kRecyclableFullType && type <= kRecyclableLastType) || type == kRecyclableUserDefinedTimestampSizeType) { if (end_of_buffer_offset_ - buffer_.size() == 0) { recycled_ = true; } header_size = kRecyclableHeaderSize; while (buffer_.size() < static_cast(kRecyclableHeaderSize)) { size_t old_size = buffer_.size(); int error = kEof; if (!TryReadMore(drop_size, &error)) { *fragment_type_or_err = error; return false; } else if (old_size == buffer_.size()) { return false; } } const uint32_t log_num = DecodeFixed32(header + 7); if (log_num != log_number_) { *fragment_type_or_err = kOldRecord; return true; } } while (header_size + length > buffer_.size()) { size_t old_size = buffer_.size(); int error = kEof; if (!TryReadMore(drop_size, &error)) { *fragment_type_or_err = error; return false; } else if (old_size == buffer_.size()) { return false; } } if (type == kZeroType && length == 0) { buffer_.clear(); *fragment_type_or_err = kBadRecord; return true; } if (checksum_) { uint32_t expected_crc = crc32c::Unmask(DecodeFixed32(header)); uint32_t actual_crc = crc32c::Value(header + 6, length + header_size - 6); if (actual_crc != expected_crc) { *drop_size = buffer_.size(); buffer_.clear(); *fragment_type_or_err = kBadRecordChecksum; return true; } } buffer_.remove_prefix(header_size + length); if (!uncompress_ || type == kSetCompressionType || type == kUserDefinedTimestampSizeType || type == kRecyclableUserDefinedTimestampSizeType) { *fragment = Slice(header + header_size, length); *fragment_type_or_err = type; return true; } else { // Uncompress compressed records uncompressed_record_.clear(); size_t uncompressed_size = 0; int remaining = 0; const char* input = header + header_size; do { remaining = uncompress_->Uncompress( input, length, uncompressed_buffer_.get(), &uncompressed_size); input = nullptr; if (remaining < 0) { buffer_.clear(); *fragment_type_or_err = kBadRecord; return true; } if (uncompressed_size > 0) { uncompressed_record_.append(uncompressed_buffer_.get(), uncompressed_size); } } while (remaining > 0 || uncompressed_size == kBlockSize); *fragment = Slice(std::move(uncompressed_record_)); *fragment_type_or_err = type; return true; } } } // namespace log } // namespace ROCKSDB_NAMESPACE