#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace DB { StorageMergeTree::StorageMergeTree( const String & path_, const String & name_, NamesAndTypesListPtr columns_, Context & context_, ASTPtr & primary_expr_ast_, const String & date_column_name_, const ASTPtr & sampling_expression_, size_t index_granularity_, const String & sign_column_, const StorageMergeTreeSettings & settings_) : path(path_), name(name_), full_path(path + escapeForFileName(name) + '/'), columns(columns_), context(context_), primary_expr_ast(primary_expr_ast_->clone()), date_column_name(date_column_name_), sampling_expression(sampling_expression_), index_granularity(index_granularity_), sign_column(sign_column_), settings(settings_), increment(full_path + "increment.txt"), log(&Logger::get("StorageMergeTree: " + name)) { min_marks_for_seek = (settings.min_rows_for_seek + index_granularity - 1) / index_granularity; min_marks_for_concurrent_read = (settings.min_rows_for_concurrent_read + index_granularity - 1) / index_granularity; /// создаём директорию, если её нет Poco::File(full_path).createDirectories(); /// инициализируем описание сортировки sort_descr.reserve(primary_expr_ast->children.size()); for (ASTs::iterator it = primary_expr_ast->children.begin(); it != primary_expr_ast->children.end(); ++it) { String name = (*it)->getColumnName(); sort_descr.push_back(SortColumnDescription(name, 1)); } context.setColumns(*columns); primary_expr = new Expression(primary_expr_ast, context); primary_key_sample = primary_expr->getSampleBlock(); merge_threads = new boost::threadpool::pool(settings.merging_threads); loadDataParts(); } StoragePtr StorageMergeTree::create( const String & path_, const String & name_, NamesAndTypesListPtr columns_, Context & context_, ASTPtr & primary_expr_ast_, const String & date_column_name_, const ASTPtr & sampling_expression_, size_t index_granularity_, const String & sign_column_, const StorageMergeTreeSettings & settings_) { return (new StorageMergeTree(path_, name_, columns_, context_, primary_expr_ast_, date_column_name_, sampling_expression_, index_granularity_, sign_column_, settings_))->thisPtr(); } StorageMergeTree::~StorageMergeTree() { joinMergeThreads(); } BlockOutputStreamPtr StorageMergeTree::write(ASTPtr query) { return new MergeTreeBlockOutputStream(thisPtr()); } BlockInputStreams StorageMergeTree::read( const Names & column_names_to_return, ASTPtr query, const Settings & settings, QueryProcessingStage::Enum & processed_stage, size_t max_block_size, unsigned threads) { check(column_names_to_return); processed_stage = QueryProcessingStage::FetchColumns; PKCondition key_condition(query, context, sort_descr); PKCondition date_condition(query, context, SortDescription(1, SortColumnDescription(date_column_name, 1))); typedef std::vector PartsList; PartsList parts; /// Выберем куски, в которых могут быть данные, удовлетворяющие date_condition. { Poco::ScopedLock lock(data_parts_mutex); for (DataParts::iterator it = data_parts.begin(); it != data_parts.end(); ++it) if (date_condition.mayBeTrueInRange(Row(1, static_cast((*it)->left_date)),Row(1, static_cast((*it)->right_date)))) parts.push_back(*it); } /// Семплирование. Names column_names_to_read = column_names_to_return; UInt64 sampling_column_value_limit = 0; typedef Poco::SharedPtr ASTFunctionPtr; ASTFunctionPtr filter_function; ExpressionPtr filter_expression; ASTSelectQuery & select = *dynamic_cast(&*query); if (select.sample_size) { double size = apply_visitor(FieldVisitorConvertToNumber(), dynamic_cast(*select.sample_size).value); if (size < 0) throw Exception("Negative sample size", ErrorCodes::ARGUMENT_OUT_OF_BOUND); if (size > 1) { size_t requested_count = apply_visitor(FieldVisitorConvertToNumber(), dynamic_cast(*select.sample_size).value); /// Узнаем, сколько строк мы бы прочли без семплирования. LOG_DEBUG(log, "Preliminary index scan with condition: " << key_condition.toString()); size_t total_count = 0; for (size_t i = 0; i < parts.size(); ++i) { DataPartPtr & part = parts[i]; MarkRanges ranges = MergeTreeBlockInputStream::markRangesFromPkRange(full_path + part->name + '/', part->size, *this, key_condition); for (size_t j = 0; j < ranges.size(); ++j) total_count += ranges[j].end - ranges[j].begin; } total_count *= index_granularity; size = std::min(1., static_cast(requested_count) / total_count); LOG_DEBUG(log, "Selected relative sample size: " << size); } UInt64 sampling_column_max = 0; DataTypePtr type = Expression(sampling_expression, context).getReturnTypes()[0]; if (type->getName() == "UInt64") sampling_column_max = std::numeric_limits::max(); else if (type->getName() == "UInt32") sampling_column_max = std::numeric_limits::max(); else if (type->getName() == "UInt16") sampling_column_max = std::numeric_limits::max(); else if (type->getName() == "UInt8") sampling_column_max = std::numeric_limits::max(); else throw Exception("Invalid sampling column type in storage parameters: " + type->getName() + ". Must be unsigned integer type.", ErrorCodes::ILLEGAL_TYPE_OF_COLUMN_FOR_FILTER); /// Добавим условие, чтобы отсечь еще что-нибудь при повторном просмотре индекса. sampling_column_value_limit = static_cast(size * sampling_column_max); if (!key_condition.addCondition(sampling_expression->getColumnName(), Range::RightBounded(sampling_column_value_limit, true))) throw Exception("Sampling column not in primary key", ErrorCodes::ILLEGAL_COLUMN); /// Выражение для фильтрации: sampling_expression <= sampling_column_value_limit ASTPtr filter_function_args = new ASTExpressionList; filter_function_args->children.push_back(sampling_expression); filter_function_args->children.push_back(new ASTLiteral(StringRange(), sampling_column_value_limit)); filter_function = new ASTFunction; filter_function->name = "lessOrEquals"; filter_function->arguments = filter_function_args; filter_function->children.push_back(filter_function->arguments); filter_expression = new Expression(filter_function, context); /// Добавим столбцы, нужные для sampling_expression. std::vector add_columns = filter_expression->getRequiredColumns(); column_names_to_read.insert(column_names_to_read.end(), add_columns.begin(), add_columns.end()); std::sort(column_names_to_read.begin(), column_names_to_read.end()); column_names_to_read.erase(std::unique(column_names_to_read.begin(), column_names_to_read.end()), column_names_to_read.end()); } LOG_DEBUG(log, "Key condition: " << key_condition.toString()); LOG_DEBUG(log, "Date condition: " << date_condition.toString()); RangesInDataParts parts_with_ranges; /// Найдем, какой диапазон читать из каждого куска. size_t sum_marks = 0; size_t sum_ranges = 0; for (size_t i = 0; i < parts.size(); ++i) { DataPartPtr & part = parts[i]; RangesInDataPart ranges(part); ranges.ranges = MergeTreeBlockInputStream::markRangesFromPkRange(full_path + part->name + '/', part->size, *this, key_condition); if (!ranges.ranges.empty()) { parts_with_ranges.push_back(ranges); sum_ranges += ranges.ranges.size(); for (size_t j = 0; j < ranges.ranges.size(); ++j) { sum_marks += ranges.ranges[j].end - ranges.ranges[j].begin; } } } LOG_DEBUG(log, "Selected " << parts.size() << " parts by date, " << parts_with_ranges.size() << " parts by key, " << sum_marks << " marks to read from " << sum_ranges << " ranges"); BlockInputStreams res; if (select.final) { /// Добавим столбцы, нужные для вычисления первичного ключа и знака. std::vector add_columns = primary_expr->getRequiredColumns(); column_names_to_read.insert(column_names_to_read.end(), add_columns.begin(), add_columns.end()); column_names_to_read.push_back(sign_column); std::sort(column_names_to_read.begin(), column_names_to_read.end()); column_names_to_read.erase(std::unique(column_names_to_read.begin(), column_names_to_read.end()), column_names_to_read.end()); res = spreadMarkRangesAmongThreadsFinal(parts_with_ranges, threads, column_names_to_read, max_block_size); } else { res = spreadMarkRangesAmongThreads(parts_with_ranges, threads, column_names_to_read, max_block_size); } if (select.sample_size) { for (size_t i = 0; i < res.size(); ++i) { BlockInputStreamPtr original_stream = res[i]; BlockInputStreamPtr expression_stream = new ExpressionBlockInputStream(original_stream, filter_expression); BlockInputStreamPtr filter_stream = new FilterBlockInputStream(expression_stream, filter_function->getColumnName()); res[i] = filter_stream; } } return res; } /// Примерно поровну распределить засечки между потоками. BlockInputStreams StorageMergeTree::spreadMarkRangesAmongThreads(RangesInDataParts parts, size_t threads, const Names & column_names, size_t max_block_size) { /// На всякий случай перемешаем куски. std::random_shuffle(parts.begin(), parts.end()); /// Посчитаем засечки для каждого куска. std::vector sum_marks_in_parts(parts.size()); size_t sum_marks = 0; for (size_t i = 0; i < parts.size(); ++i) { /// Пусть отрезки будут перечислены справа налево, чтобы можно было выбрасывать самый левый отрезок с помощью pop_back(). std::reverse(parts[i].ranges.begin(), parts[i].ranges.end()); sum_marks_in_parts[i] = 0; for (size_t j = 0; j < parts[i].ranges.size(); ++j) { MarkRange & range = parts[i].ranges[j]; sum_marks_in_parts[i] += range.end - range.begin; } sum_marks += sum_marks_in_parts[i]; } BlockInputStreams res; if (sum_marks > 0) { size_t min_marks_per_thread = (sum_marks - 1) / threads + 1; for (size_t i = 0; i < threads && !parts.empty(); ++i) { size_t need_marks = min_marks_per_thread; BlockInputStreams streams; /// Цикл по кускам. while (need_marks > 0 && !parts.empty()) { RangesInDataPart & part = parts.back(); size_t & marks_in_part = sum_marks_in_parts.back(); /// Не будем брать из куска слишком мало строк. if (marks_in_part >= min_marks_for_concurrent_read && need_marks < min_marks_for_concurrent_read) need_marks = min_marks_for_concurrent_read; /// Не будем оставлять в куске слишком мало строк. if (marks_in_part > need_marks && marks_in_part - need_marks < min_marks_for_concurrent_read) need_marks = marks_in_part; /// Возьмем весь кусок, если он достаточно мал. if (marks_in_part <= need_marks) { /// Восстановим порядок отрезков. std::reverse(part.ranges.begin(), part.ranges.end()); streams.push_back(new MergeTreeBlockInputStream(full_path + part.data_part->name + '/', max_block_size, column_names, *this, part.data_part, part.ranges, thisPtr())); need_marks -= marks_in_part; parts.pop_back(); sum_marks_in_parts.pop_back(); continue; } MarkRanges ranges_to_get_from_part; /// Цикл по отрезкам куска. while (need_marks > 0) { if (part.ranges.empty()) throw Exception("Unexpected end of ranges while spreading marks among threads", ErrorCodes::LOGICAL_ERROR); MarkRange & range = part.ranges.back(); size_t marks_in_range = range.end - range.begin; size_t marks_to_get_from_range = std::min(marks_in_range, need_marks); ranges_to_get_from_part.push_back(MarkRange(range.begin, range.begin + marks_to_get_from_range)); range.begin += marks_to_get_from_range; marks_in_part -= marks_to_get_from_range; need_marks -= marks_to_get_from_range; if (range.begin == range.end) part.ranges.pop_back(); } streams.push_back(new MergeTreeBlockInputStream(full_path + part.data_part->name + '/', max_block_size, column_names, *this, part.data_part, ranges_to_get_from_part, thisPtr())); } if (streams.size() == 1) res.push_back(streams[0]); else res.push_back(new ConcatBlockInputStream(streams)); } if (!parts.empty()) throw Exception("Couldn't spread marks among threads", ErrorCodes::LOGICAL_ERROR); } return res; } /// Распределить засечки между потоками и сделать, чтобы в ответе (почти) все данные были сколлапсированы (модификатор FINAL). BlockInputStreams StorageMergeTree::spreadMarkRangesAmongThreadsFinal(RangesInDataParts parts, size_t threads, const Names & column_names, size_t max_block_size) { ExpressionPtr sign_filter_expression; String sign_filter_column; createPositiveSignCondition(sign_filter_expression, sign_filter_column); BlockInputStreams res; BlockInputStreams to_collapse; for (size_t part_index = 0; part_index < parts.size(); ++part_index) { RangesInDataPart & part = parts[part_index]; BlockInputStreamPtr source_stream = new MergeTreeBlockInputStream(full_path + part.data_part->name + '/', max_block_size, column_names, *this, part.data_part, part.ranges, thisPtr()); if (part.data_part->size * index_granularity >= settings.min_rows_to_skip_collapsing) res.push_back(new FilterBlockInputStream(new ExpressionBlockInputStream(source_stream, sign_filter_expression), sign_filter_column)); else to_collapse.push_back(new ExpressionBlockInputStream(source_stream, primary_expr)); } if (to_collapse.size() == 1) res.push_back(to_collapse[0]); else if (to_collapse.size() > 1) res.push_back(new CollapsingFinalBlockInputStream(to_collapse, sort_descr, sign_column)); return res; } void StorageMergeTree::createPositiveSignCondition(ExpressionPtr & out_expression, String & out_column) { ASTFunction * function = new ASTFunction; ASTPtr function_ptr = function; ASTExpressionList * arguments = new ASTExpressionList; ASTPtr arguments_ptr = arguments; ASTIdentifier * sign = new ASTIdentifier; ASTPtr sign_ptr = sign; ASTLiteral * one = new ASTLiteral; ASTPtr one_ptr = one; function->name = "equals"; function->arguments = arguments_ptr; function->children.push_back(arguments_ptr); arguments->children.push_back(sign_ptr); arguments->children.push_back(one_ptr); sign->name = sign_column; sign->kind = ASTIdentifier::Column; one->type = new DataTypeInt8; one->value = Field(static_cast(1)); out_expression = new Expression(function_ptr, context); out_column = function->getColumnName(); } String StorageMergeTree::getPartName(Yandex::DayNum_t left_date, Yandex::DayNum_t right_date, UInt64 left_id, UInt64 right_id, UInt64 level) { Yandex::DateLUTSingleton & date_lut = Yandex::DateLUTSingleton::instance(); /// Имя директории для куска иммет вид: YYYYMMDD_YYYYMMDD_N_N_L. String res; { unsigned left_date_id = Yandex::Date2OrderedIdentifier(date_lut.fromDayNum(left_date)); unsigned right_date_id = Yandex::Date2OrderedIdentifier(date_lut.fromDayNum(right_date)); WriteBufferFromString wb(res); writeIntText(left_date_id, wb); writeChar('_', wb); writeIntText(right_date_id, wb); writeChar('_', wb); writeIntText(left_id, wb); writeChar('_', wb); writeIntText(right_id, wb); writeChar('_', wb); writeIntText(level, wb); } return res; } void StorageMergeTree::loadDataParts() { LOG_DEBUG(log, "Loading data parts"); Poco::ScopedLock lock(data_parts_mutex); Poco::ScopedLock lock_all(all_data_parts_mutex); Yandex::DateLUTSingleton & date_lut = Yandex::DateLUTSingleton::instance(); data_parts.clear(); static Poco::RegularExpression file_name_regexp("^(\\d{8})_(\\d{8})_(\\d+)_(\\d+)_(\\d+)"); Poco::DirectoryIterator end; Poco::RegularExpression::MatchVec matches; for (Poco::DirectoryIterator it(full_path); it != end; ++it) { std::string file_name = it.name(); if (!(file_name_regexp.match(file_name, 0, matches) && 6 == matches.size())) continue; DataPartPtr part = new DataPart(*this); part->left_date = date_lut.toDayNum(Yandex::OrderedIdentifier2Date(file_name.substr(matches[1].offset, matches[1].length))); part->right_date = date_lut.toDayNum(Yandex::OrderedIdentifier2Date(file_name.substr(matches[2].offset, matches[2].length))); part->left = Poco::NumberParser::parseUnsigned64(file_name.substr(matches[3].offset, matches[3].length)); part->right = Poco::NumberParser::parseUnsigned64(file_name.substr(matches[4].offset, matches[4].length)); part->level = Poco::NumberParser::parseUnsigned(file_name.substr(matches[5].offset, matches[5].length)); part->name = file_name; /// Размер - в количестве засечек. part->size = Poco::File(full_path + file_name + "/" + escapeForFileName(columns->front().first) + ".mrk").getSize() / MERGE_TREE_MARK_SIZE; part->modification_time = it->getLastModified().epochTime(); part->left_month = date_lut.toFirstDayNumOfMonth(part->left_date); part->right_month = date_lut.toFirstDayNumOfMonth(part->right_date); data_parts.insert(part); } all_data_parts = data_parts; /** Удаляем из набора актуальных кусков куски, которые содержатся в другом куске (которые были склеены), * но по каким-то причинам остались лежать в файловой системе. * Удаление файлов будет произведено потом в методе clearOldParts. */ if (data_parts.size() >= 2) { DataParts::iterator prev_jt = data_parts.begin(); DataParts::iterator curr_jt = prev_jt; ++curr_jt; while (curr_jt != data_parts.end()) { /// Куски данных за разные месяцы рассматривать не будем if ((*curr_jt)->left_month != (*curr_jt)->right_month || (*curr_jt)->right_month != (*prev_jt)->left_month || (*prev_jt)->left_month != (*prev_jt)->right_month) { ++prev_jt; ++curr_jt; continue; } if ((*curr_jt)->contains(**prev_jt)) { LOG_WARNING(log, "Part " << (*curr_jt)->name << " contains " << (*prev_jt)->name); data_parts.erase(prev_jt); prev_jt = curr_jt; ++curr_jt; } else if ((*prev_jt)->contains(**curr_jt)) { LOG_WARNING(log, "Part " << (*prev_jt)->name << " contains " << (*curr_jt)->name); data_parts.erase(curr_jt++); } else { ++prev_jt; ++curr_jt; } } } LOG_DEBUG(log, "Loaded data parts (" << data_parts.size() << " items)"); } void StorageMergeTree::clearOldParts() { Poco::ScopedTry lock; /// Если метод уже вызван из другого потока (или если all_data_parts прямо сейчас меняют), то можно ничего не делать. if (!lock.lock(&all_data_parts_mutex)) { LOG_TRACE(log, "Already clearing or modifying old parts"); return; } LOG_TRACE(log, "Clearing old parts"); for (DataParts::iterator it = all_data_parts.begin(); it != all_data_parts.end();) { int ref_count = it->referenceCount(); LOG_TRACE(log, (*it)->name << ": ref_count = " << ref_count); if (ref_count == 1) /// После этого ref_count не может увеличиться. { LOG_DEBUG(log, "Removing part " << (*it)->name); (*it)->remove(); all_data_parts.erase(it++); } else ++it; } } void StorageMergeTree::merge(size_t iterations, bool async) { bool while_can = false; if (iterations == 0){ while_can = true; iterations = settings.merging_threads; } for (size_t i = 0; i < iterations; ++i) merge_threads->schedule(boost::bind(&StorageMergeTree::mergeThread, this, while_can)); if (!async) joinMergeThreads(); } void StorageMergeTree::mergeThread(bool while_can) { try { std::vector parts; while (selectPartsToMerge(parts, false) || selectPartsToMerge(parts, true)) { mergeParts(parts); /// Удаляем старые куски. parts.clear(); clearOldParts(); if (!while_can) break; } } catch (const Exception & e) { LOG_ERROR(log, "Code: " << e.code() << ". " << e.displayText() << std::endl << std::endl << "Stack trace:" << std::endl << e.getStackTrace().toString()); } catch (const Poco::Exception & e) { LOG_ERROR(log, "Poco::Exception: " << e.code() << ". " << e.displayText()); } catch (const std::exception & e) { LOG_ERROR(log, "std::exception: " << e.what()); } catch (...) { LOG_ERROR(log, "Unknown exception"); } } void StorageMergeTree::joinMergeThreads() { LOG_DEBUG(log, "Waiting for merge thread to finish."); merge_threads->wait(); } /// Выбираем отрезок из не более чем max_parts_to_merge_at_once кусков так, чтобы максимальный размер был меньше чем в max_size_ratio_to_merge_parts раз больше суммы остальных. /// Это обеспечивает в худшем случае время O(n log n) на все слияния, независимо от выбора сливаемых кусков, порядка слияния и добавления. /// При max_parts_to_merge_at_once >= log(max_rows_to_merge_parts/index_granularity)/log(max_size_ratio_to_merge_parts), /// несложно доказать, что всегда будет что сливать, пока количество кусков больше /// log(max_rows_to_merge_parts/index_granularity)/log(max_size_ratio_to_merge_parts)*(количество кусков размером больше max_rows_to_merge_parts). /// Дальше эвристики. /// Будем выбирать максимальный по включению подходящий отрезок. /// Из всех таких выбираем отрезок с минимальным максимумом размера. /// Из всех таких выбираем отрезок с минимальным минимумом размера. /// Из всех таких выбираем отрезок с максимальной длиной. bool StorageMergeTree::selectPartsToMerge(std::vector & parts, bool merge_anything_for_old_months) { LOG_DEBUG(log, "Selecting parts to merge"); Poco::ScopedLock lock(data_parts_mutex); Yandex::DateLUTSingleton & date_lut = Yandex::DateLUTSingleton::instance(); size_t min_max = -1U; size_t min_min = -1U; int max_len = 0; DataParts::iterator best_begin; bool found = false; Yandex::DayNum_t now_day = date_lut.toDayNum(time(0)); Yandex::DayNum_t now_month = date_lut.toFirstDayNumOfMonth(now_day); /// Сколько кусков, начиная с текущего, можно включить в валидный отрезок, начинающийся левее текущего куска. /// Нужно для определения максимальности по включению. int max_count_from_left = 0; /// Левый конец отрезка. for (DataParts::iterator it = data_parts.begin(); it != data_parts.end(); ++it) { const DataPartPtr & first_part = *it; max_count_from_left = std::max(0, max_count_from_left - 1); /// Кусок не занят и достаточно мал. if (first_part->currently_merging || first_part->size * index_granularity > settings.max_rows_to_merge_parts) continue; /// Кусок в одном месяце. if (first_part->left_month != first_part->right_month) { LOG_WARNING(log, "Part " << first_part->name << " spans more than one month"); continue; } /// Самый длинный валидный отрезок, начинающийся здесь. size_t cur_longest_max = -1U; size_t cur_longest_min = -1U; int cur_longest_len = 0; /// Текущий отрезок, не обязательно валидный. size_t cur_max = first_part->size; size_t cur_min = first_part->size; size_t cur_sum = first_part->size; int cur_len = 1; Yandex::DayNum_t month = first_part->left_month; UInt64 cur_id = first_part->right; /// Этот месяц кончился хотя бы день назад. bool is_old_month = now_day - now_month >= 1 && now_month > month; /// Правый конец отрезка. DataParts::iterator jt = it; for (++jt; jt != data_parts.end() && cur_len < static_cast(settings.max_parts_to_merge_at_once); ++jt) { const DataPartPtr & last_part = *jt; /// Кусок не занят, достаточно мал и в одном правильном месяце. if (last_part->currently_merging || last_part->size * index_granularity > settings.max_rows_to_merge_parts || last_part->left_month != last_part->right_month || last_part->left_month != month) break; /// Кусок правее предыдущего. if (last_part->left < cur_id) { LOG_WARNING(log, "Part " << last_part->name << " intersects previous part"); break; } cur_max = std::max(cur_max, last_part->size); cur_min = std::min(cur_min, last_part->size); cur_sum += last_part->size; ++cur_len; cur_id = last_part->right; /// Если отрезок валидный, то он самый длинный валидный, начинающийся тут. if (cur_len >= 2 && (static_cast(cur_max) / (cur_sum - cur_max) < settings.max_size_ratio_to_merge_parts || (is_old_month && merge_anything_for_old_months))) /// За старый месяц объединяем что угодно, если разрешено. { cur_longest_max = cur_max; cur_longest_min = cur_min; cur_longest_len = cur_len; } } /// Это максимальный по включению валидный отрезок. if (cur_longest_len > max_count_from_left) { max_count_from_left = cur_longest_len; if (!found || std::make_pair(std::make_pair(cur_longest_max, cur_longest_min), -cur_longest_len) < std::make_pair(std::make_pair(min_max, min_min), -max_len)) { found = true; min_max = cur_longest_max; min_min = cur_longest_min; max_len = cur_longest_len; best_begin = it; } } } if (found) { parts.clear(); DataParts::iterator it = best_begin; for (int i = 0; i < max_len; ++i) { parts.push_back(*it); parts.back()->currently_merging = true; ++it; } LOG_DEBUG(log, "Selected " << parts.size() << " parts from " << parts.front()->name << " to " << parts.back()->name); } else { LOG_DEBUG(log, "No parts to merge"); } return found; } /// parts должны быть отсортированы. void StorageMergeTree::mergeParts(std::vector parts) { LOG_DEBUG(log, "Merging " << parts.size() << " parts: from " << parts.front()->name << " to " << parts.back()->name); Names all_column_names; for (NamesAndTypesList::const_iterator it = columns->begin(); it != columns->end(); ++it) all_column_names.push_back(it->first); Yandex::DateLUTSingleton & date_lut = Yandex::DateLUTSingleton::instance(); StorageMergeTree::DataPartPtr new_data_part = new DataPart(*this); new_data_part->left_date = std::numeric_limits::max(); new_data_part->right_date = std::numeric_limits::min(); new_data_part->left = parts.front()->left; new_data_part->right = parts.back()->right; new_data_part->level = 0; for (size_t i = 0; i < parts.size(); ++i) { new_data_part->level = std::max(new_data_part->level, parts[i]->level); new_data_part->left_date = std::min(new_data_part->left_date, parts[i]->left_date); new_data_part->right_date = std::max(new_data_part->right_date, parts[i]->right_date); } ++new_data_part->level; new_data_part->name = getPartName( new_data_part->left_date, new_data_part->right_date, new_data_part->left, new_data_part->right, new_data_part->level); new_data_part->left_month = date_lut.toFirstDayNumOfMonth(new_data_part->left_date); new_data_part->right_month = date_lut.toFirstDayNumOfMonth(new_data_part->right_date); /** Читаем из всех кусков, сливаем и пишем в новый. * Попутно вычисляем выражение для сортировки. */ BlockInputStreams src_streams; for (size_t i = 0; i < parts.size(); ++i) { MarkRanges ranges(1, MarkRange(0, parts[i]->size)); src_streams.push_back(new ExpressionBlockInputStream(new MergeTreeBlockInputStream( full_path + parts[i]->name + '/', DEFAULT_BLOCK_SIZE, all_column_names, *this, parts[i], ranges, StoragePtr()), primary_expr)); } /// Порядок потоков важен: при совпадении ключа элементы идет в порядке номера потока-источника. /// В слитом куске строки с одинаковым ключом должны идти в порядке возрастания идентификатора исходного куска, то есть (примерного) возрастания времени вставки. BlockInputStreamPtr merged_stream = sign_column.empty() ? new MergingSortedBlockInputStream(src_streams, sort_descr, DEFAULT_BLOCK_SIZE) : new CollapsingSortedBlockInputStream(src_streams, sort_descr, sign_column, DEFAULT_BLOCK_SIZE); MergedBlockOutputStreamPtr to = new MergedBlockOutputStream(*this, new_data_part->left_date, new_data_part->right_date, new_data_part->left, new_data_part->right, new_data_part->level); copyData(*merged_stream, *to); new_data_part->size = to->marksCount(); new_data_part->modification_time = time(0); { Poco::ScopedLock lock(data_parts_mutex); Poco::ScopedLock lock_all(all_data_parts_mutex); /// Добавляем новый кусок в набор. for (size_t i = 0; i < parts.size(); ++i) { if (data_parts.end() == data_parts.find(parts[i])) throw Exception("Logical error: cannot find data part " + parts[i]->name + " in list", ErrorCodes::LOGICAL_ERROR); } data_parts.insert(new_data_part); all_data_parts.insert(new_data_part); for (size_t i = 0; i < parts.size(); ++i) { data_parts.erase(data_parts.find(parts[i])); } } LOG_TRACE(log, "Merged " << parts.size() << " parts: from " << parts.front()->name << " to " << parts.back()->name); } void StorageMergeTree::rename(const String & new_path_to_db, const String & new_name) { joinMergeThreads(); std::string new_full_path = new_path_to_db + escapeForFileName(new_name) + '/'; Poco::File(full_path).renameTo(new_full_path); path = new_path_to_db; full_path = new_full_path; name = new_name; increment.setPath(full_path + "increment.txt"); } void StorageMergeTree::dropImpl() { joinMergeThreads(); Poco::ScopedLock lock(data_parts_mutex); Poco::ScopedLock lock_all(all_data_parts_mutex); data_parts.clear(); all_data_parts.clear(); Poco::File(full_path).remove(true); } }