#include "IMergeTreeDataPart.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace DB { namespace ErrorCodes { extern const int FILE_DOESNT_EXIST; extern const int NO_FILE_IN_DATA_PART; extern const int EXPECTED_END_OF_FILE; extern const int CORRUPTED_DATA; extern const int NOT_FOUND_EXPECTED_DATA_PART; extern const int BAD_SIZE_OF_FILE_IN_DATA_PART; extern const int BAD_TTL_FILE; extern const int CANNOT_UNLINK; extern const int NOT_IMPLEMENTED; } static ReadBufferFromFile openForReading(const String & path) { return ReadBufferFromFile(path, std::min(static_cast(DBMS_DEFAULT_BUFFER_SIZE), Poco::File(path).getSize())); } void IMergeTreeDataPart::MinMaxIndex::load(const MergeTreeData & data, const String & part_path) { size_t minmax_idx_size = data.minmax_idx_column_types.size(); parallelogram.reserve(minmax_idx_size); for (size_t i = 0; i < minmax_idx_size; ++i) { String file_name = part_path + "minmax_" + escapeForFileName(data.minmax_idx_columns[i]) + ".idx"; ReadBufferFromFile file = openForReading(file_name); const DataTypePtr & data_type = data.minmax_idx_column_types[i]; Field min_val; data_type->deserializeBinary(min_val, file); Field max_val; data_type->deserializeBinary(max_val, file); parallelogram.emplace_back(min_val, true, max_val, true); } initialized = true; } void IMergeTreeDataPart::MinMaxIndex::store(const MergeTreeData & data, const String & part_path, Checksums & out_checksums) const { store(data.minmax_idx_columns, data.minmax_idx_column_types, part_path, out_checksums); } void IMergeTreeDataPart::MinMaxIndex::store(const Names & column_names, const DataTypes & data_types, const String & part_path, Checksums & out_checksums) const { if (!initialized) throw Exception("Attempt to store uninitialized MinMax index for part " + part_path + ". This is a bug.", ErrorCodes::LOGICAL_ERROR); for (size_t i = 0; i < column_names.size(); ++i) { String file_name = "minmax_" + escapeForFileName(column_names[i]) + ".idx"; const DataTypePtr & data_type = data_types.at(i); WriteBufferFromFile out(part_path + file_name); HashingWriteBuffer out_hashing(out); data_type->serializeBinary(parallelogram[i].left, out_hashing); data_type->serializeBinary(parallelogram[i].right, out_hashing); out_hashing.next(); out_checksums.files[file_name].file_size = out_hashing.count(); out_checksums.files[file_name].file_hash = out_hashing.getHash(); } } void IMergeTreeDataPart::MinMaxIndex::update(const Block & block, const Names & column_names) { if (!initialized) parallelogram.reserve(column_names.size()); for (size_t i = 0; i < column_names.size(); ++i) { Field min_value; Field max_value; const ColumnWithTypeAndName & column = block.getByName(column_names[i]); column.column->getExtremes(min_value, max_value); if (!initialized) parallelogram.emplace_back(min_value, true, max_value, true); else { parallelogram[i].left = std::min(parallelogram[i].left, min_value); parallelogram[i].right = std::max(parallelogram[i].right, max_value); } } initialized = true; } void IMergeTreeDataPart::MinMaxIndex::merge(const MinMaxIndex & other) { if (!other.initialized) return; if (!initialized) { parallelogram = other.parallelogram; initialized = true; } else { for (size_t i = 0; i < parallelogram.size(); ++i) { parallelogram[i].left = std::min(parallelogram[i].left, other.parallelogram[i].left); parallelogram[i].right = std::max(parallelogram[i].right, other.parallelogram[i].right); } } } IMergeTreeDataPart::IMergeTreeDataPart( MergeTreeData & storage_, const String & name_, const DiskPtr & disk_, const std::optional & relative_path_, Type part_type_) : storage(storage_) , name(name_) , info(MergeTreePartInfo::fromPartName(name_, storage.format_version)) , disk(disk_) , relative_path(relative_path_.value_or(name_)) , index_granularity_info(storage_, part_type_) , part_type(part_type_) { } IMergeTreeDataPart::IMergeTreeDataPart( const MergeTreeData & storage_, const String & name_, const MergeTreePartInfo & info_, const DiskPtr & disk_, const std::optional & relative_path_, Type part_type_) : storage(storage_) , name(name_) , info(info_) , disk(disk_) , relative_path(relative_path_.value_or(name_)) , index_granularity_info(storage_, part_type_) , part_type(part_type_) { } String IMergeTreeDataPart::getNewName(const MergeTreePartInfo & new_part_info) const { if (storage.format_version < MERGE_TREE_DATA_MIN_FORMAT_VERSION_WITH_CUSTOM_PARTITIONING) { /// NOTE: getting min and max dates from the part name (instead of part data) because we want /// the merged part name be determined only by source part names. /// It is simpler this way when the real min and max dates for the block range can change /// (e.g. after an ALTER DELETE command). DayNum min_date; DayNum max_date; MergeTreePartInfo::parseMinMaxDatesFromPartName(name, min_date, max_date); return new_part_info.getPartNameV0(min_date, max_date); } else return new_part_info.getPartName(); } std::optional IMergeTreeDataPart::getColumnPosition(const String & column_name) const { auto it = column_name_to_position.find(column_name); if (it == column_name_to_position.end()) return {}; return it->second; } DayNum IMergeTreeDataPart::getMinDate() const { if (storage.minmax_idx_date_column_pos != -1 && minmax_idx.initialized) return DayNum(minmax_idx.parallelogram[storage.minmax_idx_date_column_pos].left.get()); else return DayNum(); } DayNum IMergeTreeDataPart::getMaxDate() const { if (storage.minmax_idx_date_column_pos != -1 && minmax_idx.initialized) return DayNum(minmax_idx.parallelogram[storage.minmax_idx_date_column_pos].right.get()); else return DayNum(); } time_t IMergeTreeDataPart::getMinTime() const { if (storage.minmax_idx_time_column_pos != -1 && minmax_idx.initialized) return minmax_idx.parallelogram[storage.minmax_idx_time_column_pos].left.get(); else return 0; } time_t IMergeTreeDataPart::getMaxTime() const { if (storage.minmax_idx_time_column_pos != -1 && minmax_idx.initialized) return minmax_idx.parallelogram[storage.minmax_idx_time_column_pos].right.get(); else return 0; } void IMergeTreeDataPart::setColumns(const NamesAndTypesList & new_columns) { columns = new_columns; column_name_to_position.clear(); column_name_to_position.reserve(new_columns.size()); size_t pos = 0; for (const auto & column : columns) column_name_to_position.emplace(column.name, pos++); } IMergeTreeDataPart::~IMergeTreeDataPart() = default; void IMergeTreeDataPart::removeIfNeeded() { if (state == State::DeleteOnDestroy || is_temp) { try { std::string path = getFullPath(); Poco::File dir(path); if (!dir.exists()) return; if (is_temp) { String file_name = Poco::Path(relative_path).getFileName(); if (file_name.empty()) throw Exception("relative_path " + relative_path + " of part " + name + " is invalid or not set", ErrorCodes::LOGICAL_ERROR); if (!startsWith(file_name, "tmp")) { LOG_ERROR(storage.log, "~DataPart() should remove part " << path << " but its name doesn't start with tmp. Too suspicious, keeping the part."); return; } } dir.remove(true); if (state == State::DeleteOnDestroy) { LOG_TRACE(storage.log, "Removed part from old location " << path); } } catch (...) { tryLogCurrentException(__PRETTY_FUNCTION__); } } } UInt64 IMergeTreeDataPart::getIndexSizeInBytes() const { UInt64 res = 0; for (const ColumnPtr & column : index) res += column->byteSize(); return res; } UInt64 IMergeTreeDataPart::getIndexSizeInAllocatedBytes() const { UInt64 res = 0; for (const ColumnPtr & column : index) res += column->allocatedBytes(); return res; } String IMergeTreeDataPart::stateToString(IMergeTreeDataPart::State state) { switch (state) { case State::Temporary: return "Temporary"; case State::PreCommitted: return "PreCommitted"; case State::Committed: return "Committed"; case State::Outdated: return "Outdated"; case State::Deleting: return "Deleting"; case State::DeleteOnDestroy: return "DeleteOnDestroy"; } __builtin_unreachable(); } String IMergeTreeDataPart::stateString() const { return stateToString(state); } void IMergeTreeDataPart::assertState(const std::initializer_list & affordable_states) const { if (!checkState(affordable_states)) { String states_str; for (auto affordable_state : affordable_states) states_str += stateToString(affordable_state) + " "; throw Exception("Unexpected state of part " + getNameWithState() + ". Expected: " + states_str, ErrorCodes::NOT_FOUND_EXPECTED_DATA_PART); } } void IMergeTreeDataPart::assertOnDisk() const { if (!isStoredOnDisk()) throw Exception("Data part '" + name + "' with type '" + typeToString(getType()) + "' is not stored on disk", ErrorCodes::LOGICAL_ERROR); } UInt64 IMergeTreeDataPart::getMarksCount() const { return index_granularity.getMarksCount(); } size_t IMergeTreeDataPart::getFileSizeOrZero(const String & file_name) const { auto checksum = checksums.files.find(file_name); if (checksum == checksums.files.end()) return 0; return checksum->second.file_size; } String IMergeTreeDataPart::getFullPath() const { assertOnDisk(); if (relative_path.empty()) throw Exception("Part relative_path cannot be empty. It's bug.", ErrorCodes::LOGICAL_ERROR); return storage.getFullPathOnDisk(disk) + relative_path + "/"; } void IMergeTreeDataPart::loadColumnsChecksumsIndexes(bool require_columns_checksums, bool check_consistency) { assertOnDisk(); /// Memory should not be limited during ATTACH TABLE query. /// This is already true at the server startup but must be also ensured for manual table ATTACH. /// Motivation: memory for index is shared between queries - not belong to the query itself. auto temporarily_disable_memory_tracker = getCurrentMemoryTrackerActionLock(); loadColumns(require_columns_checksums); loadChecksums(require_columns_checksums); loadIndexGranularity(); loadIndex(); /// Must be called after loadIndexGranularity as it uses the value of `index_granularity` loadColumnSizes(); loadRowsCount(); /// Must be called after loadIndex() as it uses the value of `index_granularity`. loadPartitionAndMinMaxIndex(); loadTTLInfos(); if (check_consistency) checkConsistency(require_columns_checksums); } void IMergeTreeDataPart::loadIndexGranularity() { throw Exception("Method 'loadIndexGranularity' is not implemented for part with type " + typeToString(getType()), ErrorCodes::NOT_IMPLEMENTED); } void IMergeTreeDataPart::loadIndex() { /// It can be empty in case of mutations if (!index_granularity.isInitialized()) throw Exception("Index granularity is not loaded before index loading", ErrorCodes::LOGICAL_ERROR); size_t key_size = storage.primary_key_columns.size(); if (key_size) { MutableColumns loaded_index; loaded_index.resize(key_size); for (size_t i = 0; i < key_size; ++i) { loaded_index[i] = storage.primary_key_data_types[i]->createColumn(); loaded_index[i]->reserve(index_granularity.getMarksCount()); } String index_path = getFullPath() + "primary.idx"; ReadBufferFromFile index_file = openForReading(index_path); for (size_t i = 0; i < index_granularity.getMarksCount(); ++i) //-V756 for (size_t j = 0; j < key_size; ++j) storage.primary_key_data_types[j]->deserializeBinary(*loaded_index[j], index_file); for (size_t i = 0; i < key_size; ++i) { loaded_index[i]->protect(); if (loaded_index[i]->size() != index_granularity.getMarksCount()) throw Exception("Cannot read all data from index file " + index_path + "(expected size: " + toString(index_granularity.getMarksCount()) + ", read: " + toString(loaded_index[i]->size()) + ")", ErrorCodes::CANNOT_READ_ALL_DATA); } if (!index_file.eof()) throw Exception("Index file " + index_path + " is unexpectedly long", ErrorCodes::EXPECTED_END_OF_FILE); index.assign(std::make_move_iterator(loaded_index.begin()), std::make_move_iterator(loaded_index.end())); } } void IMergeTreeDataPart::loadPartitionAndMinMaxIndex() { if (storage.format_version < MERGE_TREE_DATA_MIN_FORMAT_VERSION_WITH_CUSTOM_PARTITIONING) { DayNum min_date; DayNum max_date; MergeTreePartInfo::parseMinMaxDatesFromPartName(name, min_date, max_date); const auto & date_lut = DateLUT::instance(); partition = MergeTreePartition(date_lut.toNumYYYYMM(min_date)); minmax_idx = MinMaxIndex(min_date, max_date); } else { String path = getFullPath(); partition.load(storage, path); if (!isEmpty()) minmax_idx.load(storage, path); } String calculated_partition_id = partition.getID(storage.partition_key_sample); if (calculated_partition_id != info.partition_id) throw Exception( "While loading part " + getFullPath() + ": calculated partition ID: " + calculated_partition_id + " differs from partition ID in part name: " + info.partition_id, ErrorCodes::CORRUPTED_DATA); } void IMergeTreeDataPart::loadChecksums(bool require) { String path = getFullPath() + "checksums.txt"; Poco::File checksums_file(path); if (checksums_file.exists()) { ReadBufferFromFile file = openForReading(path); if (checksums.read(file)) { assertEOF(file); bytes_on_disk = checksums.getTotalSizeOnDisk(); } else bytes_on_disk = calculateTotalSizeOnDisk(getFullPath()); } else { if (require) throw Exception("No checksums.txt in part " + name, ErrorCodes::NO_FILE_IN_DATA_PART); bytes_on_disk = calculateTotalSizeOnDisk(getFullPath()); } } void IMergeTreeDataPart::loadRowsCount() { if (index_granularity.empty()) { rows_count = 0; } else if (storage.format_version >= MERGE_TREE_DATA_MIN_FORMAT_VERSION_WITH_CUSTOM_PARTITIONING) { String path = getFullPath() + "count.txt"; if (!Poco::File(path).exists()) throw Exception("No count.txt in part " + name, ErrorCodes::NO_FILE_IN_DATA_PART); ReadBufferFromFile file = openForReading(path); readIntText(rows_count, file); assertEOF(file); } else { for (const NameAndTypePair & column : columns) { ColumnPtr column_col = column.type->createColumn(); if (!column_col->isFixedAndContiguous() || column_col->lowCardinality()) continue; size_t column_size = getColumnSize(column.name, *column.type).data_uncompressed; if (!column_size) continue; size_t sizeof_field = column_col->sizeOfValueIfFixed(); rows_count = column_size / sizeof_field; if (column_size % sizeof_field != 0) { throw Exception( "Uncompressed size of column " + column.name + "(" + toString(column_size) + ") is not divisible by the size of value (" + toString(sizeof_field) + ")", ErrorCodes::LOGICAL_ERROR); } size_t last_mark_index_granularity = index_granularity.getLastNonFinalMarkRows(); size_t rows_approx = index_granularity.getTotalRows(); if (!(rows_count <= rows_approx && rows_approx < rows_count + last_mark_index_granularity)) throw Exception( "Unexpected size of column " + column.name + ": " + toString(rows_count) + " rows, expected " + toString(rows_approx) + "+-" + toString(last_mark_index_granularity) + " rows according to the index", ErrorCodes::LOGICAL_ERROR); return; } throw Exception("Data part doesn't contain fixed size column (even Date column)", ErrorCodes::LOGICAL_ERROR); } } void IMergeTreeDataPart::loadTTLInfos() { String path = getFullPath() + "ttl.txt"; if (Poco::File(path).exists()) { ReadBufferFromFile in = openForReading(path); assertString("ttl format version: ", in); size_t format_version; readText(format_version, in); assertChar('\n', in); if (format_version == 1) { try { ttl_infos.read(in); } catch (const JSONException &) { throw Exception("Error while parsing file ttl.txt in part: " + name, ErrorCodes::BAD_TTL_FILE); } } else throw Exception("Unknown ttl format version: " + toString(format_version), ErrorCodes::BAD_TTL_FILE); } } void IMergeTreeDataPart::loadColumns(bool require) { String path = getFullPath() + "columns.txt"; Poco::File poco_file_path{path}; if (!poco_file_path.exists()) { if (require || isCompactPart(shared_from_this())) throw Exception("No columns.txt in part " + name, ErrorCodes::NO_FILE_IN_DATA_PART); /// If there is no file with a list of columns, write it down. for (const NameAndTypePair & column : storage.getColumns().getAllPhysical()) if (Poco::File(getFullPath() + getFileNameForColumn(column) + ".bin").exists()) columns.push_back(column); if (columns.empty()) throw Exception("No columns in part " + name, ErrorCodes::NO_FILE_IN_DATA_PART); { WriteBufferFromFile out(path + ".tmp", 4096); columns.writeText(out); } Poco::File(path + ".tmp").renameTo(path); } else { is_frozen = !poco_file_path.canWrite(); ReadBufferFromFile file = openForReading(path); columns.readText(file); } size_t pos = 0; for (const auto & column : columns) column_name_to_position.emplace(column.name, pos++); } void IMergeTreeDataPart::loadColumnSizes() { size_t columns_num = columns.size(); if (columns_num == 0) throw Exception("No columns in part " + name, ErrorCodes::NO_FILE_IN_DATA_PART); auto column_sizes_path = getFullPath() + "columns_sizes.txt"; auto columns_sizes_file = Poco::File(column_sizes_path); if (!columns_sizes_file.exists()) return; ReadBufferFromFile buffer(column_sizes_path, columns_sizes_file.getSize()); auto it = columns.begin(); for (size_t i = 0; i < columns_num; ++i, ++it) readPODBinary(columns_sizes[it->name], buffer); assertEOF(buffer); } UInt64 IMergeTreeDataPart::calculateTotalSizeOnDisk(const String & from) { Poco::File cur(from); if (cur.isFile()) return cur.getSize(); std::vector files; cur.list(files); UInt64 res = 0; for (const auto & file : files) res += calculateTotalSizeOnDisk(from + file); return res; } void IMergeTreeDataPart::renameTo(const String & new_relative_path, bool remove_new_dir_if_exists) const { assertOnDisk(); String from = getFullPath(); String to = storage.getFullPathOnDisk(disk) + new_relative_path + "/"; Poco::File from_file(from); if (!from_file.exists()) throw Exception("Part directory " + from + " doesn't exist. Most likely it is logical error.", ErrorCodes::FILE_DOESNT_EXIST); Poco::File to_file(to); if (to_file.exists()) { if (remove_new_dir_if_exists) { Names files; Poco::File(from).list(files); LOG_WARNING(storage.log, "Part directory " << to << " already exists" << " and contains " << files.size() << " files. Removing it."); to_file.remove(true); } else { throw Exception("Part directory " + to + " already exists", ErrorCodes::DIRECTORY_ALREADY_EXISTS); } } from_file.setLastModified(Poco::Timestamp::fromEpochTime(time(nullptr))); from_file.renameTo(to); relative_path = new_relative_path; } void IMergeTreeDataPart::remove() const { if (!isStoredOnDisk()) return; if (relative_path.empty()) throw Exception("Part relative_path cannot be empty. This is bug.", ErrorCodes::LOGICAL_ERROR); /** Atomic directory removal: * - rename directory to temporary name; * - remove it recursive. * * For temporary name we use "delete_tmp_" prefix. * * NOTE: We cannot use "tmp_delete_" prefix, because there is a second thread, * that calls "clearOldTemporaryDirectories" and removes all directories, that begin with "tmp_" and are old enough. * But when we removing data part, it can be old enough. And rename doesn't change mtime. * And a race condition can happen that will lead to "File not found" error here. */ String full_path = storage.getFullPathOnDisk(disk); String from = full_path + relative_path; String to = full_path + "delete_tmp_" + name; // TODO directory delete_tmp_ is never removed if server crashes before returning from this function Poco::File from_dir{from}; Poco::File to_dir{to}; if (to_dir.exists()) { LOG_WARNING(storage.log, "Directory " << to << " (to which part must be renamed before removing) already exists." " Most likely this is due to unclean restart. Removing it."); try { to_dir.remove(true); } catch (...) { LOG_ERROR(storage.log, "Cannot remove directory " << to << ". Check owner and access rights."); throw; } } try { from_dir.renameTo(to); } catch (const Poco::FileNotFoundException &) { LOG_ERROR(storage.log, "Directory " << from << " (part to remove) doesn't exist or one of nested files has gone." " Most likely this is due to manual removing. This should be discouraged. Ignoring."); return; } try { /// Remove each expected file in directory, then remove directory itself. #if !__clang__ #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-variable" #endif std::shared_lock lock(columns_lock); for (const auto & [file, _] : checksums.files) { String path_to_remove = to + "/" + file; if (0 != unlink(path_to_remove.c_str())) throwFromErrnoWithPath("Cannot unlink file " + path_to_remove, path_to_remove, ErrorCodes::CANNOT_UNLINK); } #if !__clang__ #pragma GCC diagnostic pop #endif for (const auto & file : {"checksums.txt", "columns.txt"}) { String path_to_remove = to + "/" + file; if (0 != unlink(path_to_remove.c_str())) throwFromErrnoWithPath("Cannot unlink file " + path_to_remove, path_to_remove, ErrorCodes::CANNOT_UNLINK); } if (0 != rmdir(to.c_str())) throwFromErrnoWithPath("Cannot rmdir file " + to, to, ErrorCodes::CANNOT_UNLINK); } catch (...) { /// Recursive directory removal does many excessive "stat" syscalls under the hood. LOG_ERROR(storage.log, "Cannot quickly remove directory " << to << " by removing files; fallback to recursive removal. Reason: " << getCurrentExceptionMessage(false)); to_dir.remove(true); } } void IMergeTreeDataPart::accumulateColumnSizes(ColumnToSize & /* column_to_size */) const { throw Exception("Method 'accumulateColumnSizes' is not supported for data part with type " + typeToString(getType()), ErrorCodes::NOT_IMPLEMENTED); } void IMergeTreeDataPart::checkConsistency(bool /* require_part_metadata */) const { throw Exception("Method 'checkConsistency' is not supported for data part with type " + typeToString(getType()), ErrorCodes::NOT_IMPLEMENTED); } String IMergeTreeDataPart::typeToString(Type type) { switch (type) { case Type::WIDE: return "Wide"; case Type::COMPACT: return "Compact"; case Type::IN_MEMORY: return "InMemory"; case Type::UNKNOWN: return "Unknown"; } __builtin_unreachable(); } String IMergeTreeDataPart::getRelativePathForDetachedPart(const String & prefix) const { /// Do not allow underscores in the prefix because they are used as separators. assert(prefix.find_first_of('_') == String::npos); String res; /** If you need to detach a part, and directory into which we want to rename it already exists, * we will rename to the directory with the name to which the suffix is added in the form of "_tryN". * This is done only in the case of `to_detached`, because it is assumed that in this case the exact name does not matter. * No more than 10 attempts are made so that there are not too many junk directories left. */ for (int try_no = 0; try_no < 10; try_no++) { res = "detached/" + (prefix.empty() ? "" : prefix + "_") + name + (try_no ? "_try" + DB::toString(try_no) : ""); if (!Poco::File(storage.getFullPathOnDisk(disk) + res).exists()) return res; LOG_WARNING(storage.log, "Directory " << res << " (to detach to) already exists." " Will detach to directory with '_tryN' suffix."); } return res; } void IMergeTreeDataPart::renameToDetached(const String & prefix) const { assertOnDisk(); renameTo(getRelativePathForDetachedPart(prefix)); } void IMergeTreeDataPart::makeCloneInDetached(const String & prefix) const { assertOnDisk(); LOG_INFO(storage.log, "Detaching " << relative_path); Poco::Path src(getFullPath()); Poco::Path dst(storage.getFullPathOnDisk(disk) + getRelativePathForDetachedPart(prefix)); /// Backup is not recursive (max_level is 0), so do not copy inner directories localBackup(src, dst, 0); } void IMergeTreeDataPart::makeCloneOnDiskDetached(const ReservationPtr & reservation) const { assertOnDisk(); auto reserved_disk = reservation->getDisk(); if (reserved_disk->getName() == disk->getName()) throw Exception("Can not clone data part " + name + " to same disk " + disk->getName(), ErrorCodes::LOGICAL_ERROR); String path_to_clone = storage.getFullPathOnDisk(reserved_disk) + "detached/"; if (Poco::File(path_to_clone + relative_path).exists()) throw Exception("Path " + path_to_clone + relative_path + " already exists. Can not clone ", ErrorCodes::DIRECTORY_ALREADY_EXISTS); Poco::File(path_to_clone).createDirectory(); Poco::File cloning_directory(getFullPath()); cloning_directory.copyTo(path_to_clone); } bool isCompactPart(const MergeTreeDataPartPtr & data_part) { return (data_part && data_part->getType() == MergeTreeDataPartType::COMPACT); } bool isWidePart(const MergeTreeDataPartPtr & data_part) { return (data_part && data_part->getType() == MergeTreeDataPartType::WIDE); } }