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ClickHouse/src/Storages/MergeTree/MergeTreeData.cpp
alesapin 9ebf1b4fad Get rid of separate minmax index fields
2021-03-02 13:33:54 +03:00

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#include <Compression/CompressedReadBuffer.h>
#include <DataStreams/copyData.h>
#include <DataTypes/DataTypeArray.h>
#include <DataTypes/DataTypeDate.h>
#include <DataTypes/DataTypeDateTime.h>
#include <DataTypes/DataTypeEnum.h>
#include <DataTypes/DataTypeUUID.h>
#include <DataTypes/DataTypeNullable.h>
#include <DataTypes/DataTypeLowCardinality.h>
#include <DataTypes/NestedUtils.h>
#include <Formats/FormatFactory.h>
#include <Processors/Formats/InputStreamFromInputFormat.h>
#include <Functions/FunctionFactory.h>
#include <Functions/IFunction.h>
#include <IO/ConcatReadBuffer.h>
#include <IO/Operators.h>
#include <IO/ReadBufferFromMemory.h>
#include <IO/WriteBufferFromString.h>
#include <Interpreters/ExpressionAnalyzer.h>
#include <Interpreters/PartLog.h>
#include <Interpreters/TreeRewriter.h>
#include <Interpreters/Context.h>
#include <Interpreters/inplaceBlockConversions.h>
#include <Parsers/ASTFunction.h>
#include <Parsers/ASTLiteral.h>
#include <Parsers/ASTNameTypePair.h>
#include <Parsers/ASTPartition.h>
#include <Parsers/ASTSetQuery.h>
#include <Parsers/ExpressionListParsers.h>
#include <Parsers/parseQuery.h>
#include <Parsers/queryToString.h>
#include <Storages/AlterCommands.h>
#include <Storages/MergeTree/MergeTreeData.h>
#include <Storages/MergeTree/MergeTreeDataPartInMemory.h>
#include <Storages/MergeTree/MergeTreeDataPartCompact.h>
#include <Storages/MergeTree/MergeTreeDataPartWide.h>
#include <Storages/MergeTree/MergeTreeSequentialSource.h>
#include <Storages/MergeTree/MergedBlockOutputStream.h>
#include <Storages/MergeTree/MergedColumnOnlyOutputStream.h>
#include <Storages/MergeTree/checkDataPart.h>
#include <Storages/MergeTree/localBackup.h>
#include <Storages/StorageMergeTree.h>
#include <Storages/StorageReplicatedMergeTree.h>
#include <Common/Increment.h>
#include <Common/SimpleIncrement.h>
#include <Common/Stopwatch.h>
#include <Common/StringUtils/StringUtils.h>
#include <Common/escapeForFileName.h>
#include <Common/quoteString.h>
#include <Common/typeid_cast.h>
#include <Poco/DirectoryIterator.h>
#include <boost/range/adaptor/filtered.hpp>
#include <boost/algorithm/string/join.hpp>
#include <algorithm>
#include <iomanip>
#include <optional>
#include <set>
#include <thread>
#include <typeinfo>
#include <typeindex>
#include <unordered_set>
namespace ProfileEvents
{
extern const Event RejectedInserts;
extern const Event DelayedInserts;
extern const Event DelayedInsertsMilliseconds;
}
namespace CurrentMetrics
{
extern const Metric DelayedInserts;
extern const Metric BackgroundMovePoolTask;
}
namespace
{
constexpr UInt64 RESERVATION_MIN_ESTIMATION_SIZE = 1u * 1024u * 1024u; /// 1MB
}
namespace DB
{
namespace ErrorCodes
{
extern const int NO_SUCH_DATA_PART;
extern const int NOT_IMPLEMENTED;
extern const int DIRECTORY_ALREADY_EXISTS;
extern const int TOO_MANY_UNEXPECTED_DATA_PARTS;
extern const int DUPLICATE_DATA_PART;
extern const int NO_SUCH_COLUMN_IN_TABLE;
extern const int LOGICAL_ERROR;
extern const int ILLEGAL_COLUMN;
extern const int CORRUPTED_DATA;
extern const int BAD_TYPE_OF_FIELD;
extern const int BAD_ARGUMENTS;
extern const int INVALID_PARTITION_VALUE;
extern const int METADATA_MISMATCH;
extern const int PART_IS_TEMPORARILY_LOCKED;
extern const int TOO_MANY_PARTS;
extern const int INCOMPATIBLE_COLUMNS;
extern const int BAD_TTL_EXPRESSION;
extern const int INCORRECT_FILE_NAME;
extern const int BAD_DATA_PART_NAME;
extern const int READONLY_SETTING;
extern const int ABORTED;
extern const int UNKNOWN_PART_TYPE;
extern const int UNKNOWN_DISK;
extern const int NOT_ENOUGH_SPACE;
extern const int ALTER_OF_COLUMN_IS_FORBIDDEN;
extern const int SUPPORT_IS_DISABLED;
extern const int TOO_MANY_SIMULTANEOUS_QUERIES;
}
static void checkSampleExpression(const StorageInMemoryMetadata & metadata, bool allow_sampling_expression_not_in_primary_key)
{
const auto & pk_sample_block = metadata.getPrimaryKey().sample_block;
if (!pk_sample_block.has(metadata.sampling_key.column_names[0]) && !allow_sampling_expression_not_in_primary_key)
throw Exception("Sampling expression must be present in the primary key", ErrorCodes::BAD_ARGUMENTS);
}
MergeTreeData::MergeTreeData(
const StorageID & table_id_,
const String & relative_data_path_,
const StorageInMemoryMetadata & metadata_,
Context & context_,
const String & date_column_name,
const MergingParams & merging_params_,
std::unique_ptr<MergeTreeSettings> storage_settings_,
bool require_part_metadata_,
bool attach,
BrokenPartCallback broken_part_callback_)
: IStorage(table_id_)
, global_context(context_.getGlobalContext())
, merging_params(merging_params_)
, require_part_metadata(require_part_metadata_)
, relative_data_path(relative_data_path_)
, broken_part_callback(broken_part_callback_)
, log_name(table_id_.getNameForLogs())
, log(&Poco::Logger::get(log_name))
, storage_settings(std::move(storage_settings_))
, data_parts_by_info(data_parts_indexes.get<TagByInfo>())
, data_parts_by_state_and_info(data_parts_indexes.get<TagByStateAndInfo>())
, parts_mover(this)
{
const auto settings = getSettings();
allow_nullable_key = attach || settings->allow_nullable_key;
if (relative_data_path.empty())
throw Exception("MergeTree storages require data path", ErrorCodes::INCORRECT_FILE_NAME);
/// Check sanity of MergeTreeSettings. Only when table is created.
if (!attach)
settings->sanityCheck(global_context.getSettingsRef());
MergeTreeDataFormatVersion min_format_version(0);
if (!date_column_name.empty())
{
try
{
checkPartitionKeyAndInitMinMax(metadata_.partition_key);
setProperties(metadata_, metadata_, attach);
if (minmax_idx_date_column_pos == -1)
throw Exception("Could not find Date column", ErrorCodes::BAD_TYPE_OF_FIELD);
}
catch (Exception & e)
{
/// Better error message.
e.addMessage("(while initializing MergeTree partition key from date column " + backQuote(date_column_name) + ")");
throw;
}
}
else
{
is_custom_partitioned = true;
checkPartitionKeyAndInitMinMax(metadata_.partition_key);
min_format_version = MERGE_TREE_DATA_MIN_FORMAT_VERSION_WITH_CUSTOM_PARTITIONING;
}
setProperties(metadata_, metadata_, attach);
/// NOTE: using the same columns list as is read when performing actual merges.
merging_params.check(metadata_);
if (metadata_.sampling_key.definition_ast != nullptr)
{
/// This is for backward compatibility.
checkSampleExpression(metadata_, attach || settings->compatibility_allow_sampling_expression_not_in_primary_key);
}
checkTTLExpressions(metadata_, metadata_);
/// format_file always contained on any data path
PathWithDisk version_file;
/// Creating directories, if not exist.
for (const auto & [path, disk] : getRelativeDataPathsWithDisks())
{
disk->createDirectories(path);
disk->createDirectories(path + "detached");
auto current_version_file_path = path + "format_version.txt";
if (disk->exists(current_version_file_path))
{
if (!version_file.first.empty())
{
LOG_ERROR(log, "Duplication of version file {} and {}", fullPath(version_file.second, version_file.first), current_version_file_path);
throw Exception("Multiple format_version.txt file", ErrorCodes::CORRUPTED_DATA);
}
version_file = {current_version_file_path, disk};
}
}
/// If not choose any
if (version_file.first.empty())
version_file = {relative_data_path + "format_version.txt", getStoragePolicy()->getAnyDisk()};
bool version_file_exists = version_file.second->exists(version_file.first);
// When data path or file not exists, ignore the format_version check
if (!attach || !version_file_exists)
{
format_version = min_format_version;
auto buf = version_file.second->writeFile(version_file.first);
writeIntText(format_version.toUnderType(), *buf);
if (global_context.getSettingsRef().fsync_metadata)
buf->sync();
}
else
{
auto buf = version_file.second->readFile(version_file.first);
UInt32 read_format_version;
readIntText(read_format_version, *buf);
format_version = read_format_version;
if (!buf->eof())
throw Exception("Bad version file: " + fullPath(version_file.second, version_file.first), ErrorCodes::CORRUPTED_DATA);
}
if (format_version < min_format_version)
{
if (min_format_version == MERGE_TREE_DATA_MIN_FORMAT_VERSION_WITH_CUSTOM_PARTITIONING.toUnderType())
throw Exception(
"MergeTree data format version on disk doesn't support custom partitioning",
ErrorCodes::METADATA_MISMATCH);
}
String reason;
if (!canUsePolymorphicParts(*settings, &reason) && !reason.empty())
LOG_WARNING(log, "{} Settings 'min_rows_for_wide_part', 'min_bytes_for_wide_part', "
"'min_rows_for_compact_part' and 'min_bytes_for_compact_part' will be ignored.", reason);
}
StoragePolicyPtr MergeTreeData::getStoragePolicy() const
{
return global_context.getStoragePolicy(getSettings()->storage_policy);
}
static void checkKeyExpression(const ExpressionActions & expr, const Block & sample_block, const String & key_name, bool allow_nullable_key)
{
for (const auto & action : expr.getActions())
{
if (action.node->type == ActionsDAG::ActionType::ARRAY_JOIN)
throw Exception(key_name + " key cannot contain array joins", ErrorCodes::ILLEGAL_COLUMN);
if (action.node->type == ActionsDAG::ActionType::FUNCTION)
{
IFunctionBase & func = *action.node->function_base;
if (!func.isDeterministic())
throw Exception(key_name + " key cannot contain non-deterministic functions, "
"but contains function " + func.getName(),
ErrorCodes::BAD_ARGUMENTS);
}
}
for (const ColumnWithTypeAndName & element : sample_block)
{
const ColumnPtr & column = element.column;
if (column && (isColumnConst(*column) || column->isDummy()))
throw Exception{key_name + " key cannot contain constants", ErrorCodes::ILLEGAL_COLUMN};
if (!allow_nullable_key && element.type->isNullable())
throw Exception{key_name + " key cannot contain nullable columns", ErrorCodes::ILLEGAL_COLUMN};
}
}
void MergeTreeData::checkProperties(
const StorageInMemoryMetadata & new_metadata, const StorageInMemoryMetadata & old_metadata, bool attach) const
{
if (!new_metadata.sorting_key.definition_ast)
throw Exception("ORDER BY cannot be empty", ErrorCodes::BAD_ARGUMENTS);
KeyDescription new_sorting_key = new_metadata.sorting_key;
KeyDescription new_primary_key = new_metadata.primary_key;
size_t sorting_key_size = new_sorting_key.column_names.size();
size_t primary_key_size = new_primary_key.column_names.size();
if (primary_key_size > sorting_key_size)
throw Exception("Primary key must be a prefix of the sorting key, but its length: "
+ toString(primary_key_size) + " is greater than the sorting key length: " + toString(sorting_key_size),
ErrorCodes::BAD_ARGUMENTS);
NameSet primary_key_columns_set;
for (size_t i = 0; i < sorting_key_size; ++i)
{
const String & sorting_key_column = new_sorting_key.column_names[i];
if (i < primary_key_size)
{
const String & pk_column = new_primary_key.column_names[i];
if (pk_column != sorting_key_column)
throw Exception("Primary key must be a prefix of the sorting key, but in position "
+ toString(i) + " its column is " + pk_column + ", not " + sorting_key_column,
ErrorCodes::BAD_ARGUMENTS);
if (!primary_key_columns_set.emplace(pk_column).second)
throw Exception("Primary key contains duplicate columns", ErrorCodes::BAD_ARGUMENTS);
}
}
auto all_columns = new_metadata.columns.getAllPhysical();
/// Order by check AST
if (old_metadata.hasSortingKey())
{
/// This is ALTER, not CREATE/ATTACH TABLE. Let us check that all new columns used in the sorting key
/// expression have just been added (so that the sorting order is guaranteed to be valid with the new key).
Names new_primary_key_columns = new_primary_key.column_names;
Names new_sorting_key_columns = new_sorting_key.column_names;
ASTPtr added_key_column_expr_list = std::make_shared<ASTExpressionList>();
const auto & old_sorting_key_columns = old_metadata.getSortingKeyColumns();
for (size_t new_i = 0, old_i = 0; new_i < sorting_key_size; ++new_i)
{
if (old_i < old_sorting_key_columns.size())
{
if (new_sorting_key_columns[new_i] != old_sorting_key_columns[old_i])
added_key_column_expr_list->children.push_back(new_sorting_key.expression_list_ast->children[new_i]);
else
++old_i;
}
else
added_key_column_expr_list->children.push_back(new_sorting_key.expression_list_ast->children[new_i]);
}
if (!added_key_column_expr_list->children.empty())
{
auto syntax = TreeRewriter(global_context).analyze(added_key_column_expr_list, all_columns);
Names used_columns = syntax->requiredSourceColumns();
NamesAndTypesList deleted_columns;
NamesAndTypesList added_columns;
old_metadata.getColumns().getAllPhysical().getDifference(all_columns, deleted_columns, added_columns);
for (const String & col : used_columns)
{
if (!added_columns.contains(col) || deleted_columns.contains(col))
throw Exception("Existing column " + backQuoteIfNeed(col) + " is used in the expression that was "
"added to the sorting key. You can add expressions that use only the newly added columns",
ErrorCodes::BAD_ARGUMENTS);
if (new_metadata.columns.getDefaults().count(col))
throw Exception("Newly added column " + backQuoteIfNeed(col) + " has a default expression, so adding "
"expressions that use it to the sorting key is forbidden",
ErrorCodes::BAD_ARGUMENTS);
}
}
}
if (!new_metadata.secondary_indices.empty())
{
std::unordered_set<String> indices_names;
for (const auto & index : new_metadata.secondary_indices)
{
MergeTreeIndexFactory::instance().validate(index, attach);
if (indices_names.find(index.name) != indices_names.end())
throw Exception(
"Index with name " + backQuote(index.name) + " already exists",
ErrorCodes::LOGICAL_ERROR);
indices_names.insert(index.name);
}
}
checkKeyExpression(*new_sorting_key.expression, new_sorting_key.sample_block, "Sorting", allow_nullable_key);
}
void MergeTreeData::setProperties(const StorageInMemoryMetadata & new_metadata, const StorageInMemoryMetadata & old_metadata, bool attach)
{
checkProperties(new_metadata, old_metadata, attach);
setInMemoryMetadata(new_metadata);
}
namespace
{
ExpressionActionsPtr getCombinedIndicesExpression(
const KeyDescription & key,
const IndicesDescription & indices,
const ColumnsDescription & columns,
const Context & context)
{
ASTPtr combined_expr_list = key.expression_list_ast->clone();
for (const auto & index : indices)
for (const auto & index_expr : index.expression_list_ast->children)
combined_expr_list->children.push_back(index_expr->clone());
auto syntax_result = TreeRewriter(context).analyze(combined_expr_list, columns.getAllPhysical());
return ExpressionAnalyzer(combined_expr_list, syntax_result, context).getActions(false);
}
}
ExpressionActionsPtr MergeTreeData::getMinMaxExpr(const KeyDescription & partition_key) const
{
NamesAndTypesList partition_key_columns;
if (!partition_key.column_names.empty())
partition_key_columns = partition_key.expression->getRequiredColumnsWithTypes();
return std::make_shared<ExpressionActions>(std::make_shared<ActionsDAG>(partition_key_columns));
}
Names MergeTreeData::getMinMaxColumnsNames(const KeyDescription & partition_key) const
{
if (!partition_key.column_names.empty())
return partition_key.expression->getRequiredColumns();
return {};
}
DataTypes MergeTreeData::getMinMaxColumnsTypes(const KeyDescription & partition_key) const
{
if (!partition_key.column_names.empty())
return partition_key.expression->getRequiredColumnsWithTypes().getTypes();
return {};
}
ExpressionActionsPtr MergeTreeData::getPrimaryKeyAndSkipIndicesExpression(const StorageMetadataPtr & metadata_snapshot) const
{
return getCombinedIndicesExpression(metadata_snapshot->getPrimaryKey(), metadata_snapshot->getSecondaryIndices(), metadata_snapshot->getColumns(), global_context);
}
ExpressionActionsPtr MergeTreeData::getSortingKeyAndSkipIndicesExpression(const StorageMetadataPtr & metadata_snapshot) const
{
return getCombinedIndicesExpression(metadata_snapshot->getSortingKey(), metadata_snapshot->getSecondaryIndices(), metadata_snapshot->getColumns(), global_context);
}
void MergeTreeData::checkPartitionKeyAndInitMinMax(const KeyDescription & new_partition_key)
{
if (new_partition_key.expression_list_ast->children.empty())
return;
checkKeyExpression(*new_partition_key.expression, new_partition_key.sample_block, "Partition", allow_nullable_key);
/// Add all columns used in the partition key to the min-max index.
DataTypes minmax_idx_columns_types = getMinMaxColumnsTypes(new_partition_key);
/// Try to find the date column in columns used by the partition key (a common case).
bool encountered_date_column = false;
for (size_t i = 0; i < minmax_idx_columns_types.size(); ++i)
{
if (typeid_cast<const DataTypeDate *>(minmax_idx_columns_types[i].get()))
{
if (!encountered_date_column)
{
minmax_idx_date_column_pos = i;
encountered_date_column = true;
}
else
{
/// There is more than one Date column in partition key and we don't know which one to choose.
minmax_idx_date_column_pos = -1;
}
}
}
if (!encountered_date_column)
{
for (size_t i = 0; i < minmax_idx_columns_types.size(); ++i)
{
if (typeid_cast<const DataTypeDateTime *>(minmax_idx_columns_types[i].get()))
{
if (!encountered_date_column)
{
minmax_idx_time_column_pos = i;
encountered_date_column = true;
}
else
{
/// There is more than one DateTime column in partition key and we don't know which one to choose.
minmax_idx_time_column_pos = -1;
}
}
}
}
}
void MergeTreeData::checkTTLExpressions(const StorageInMemoryMetadata & new_metadata, const StorageInMemoryMetadata & old_metadata) const
{
auto new_column_ttls = new_metadata.column_ttls_by_name;
if (!new_column_ttls.empty())
{
NameSet columns_ttl_forbidden;
if (old_metadata.hasPartitionKey())
for (const auto & col : old_metadata.getColumnsRequiredForPartitionKey())
columns_ttl_forbidden.insert(col);
if (old_metadata.hasSortingKey())
for (const auto & col : old_metadata.getColumnsRequiredForSortingKey())
columns_ttl_forbidden.insert(col);
for (const auto & [name, ttl_description] : new_column_ttls)
{
if (columns_ttl_forbidden.count(name))
throw Exception("Trying to set TTL for key column " + name, ErrorCodes::ILLEGAL_COLUMN);
}
}
auto new_table_ttl = new_metadata.table_ttl;
if (new_table_ttl.definition_ast)
{
for (const auto & move_ttl : new_table_ttl.move_ttl)
{
if (!getDestinationForMoveTTL(move_ttl))
{
String message;
if (move_ttl.destination_type == DataDestinationType::DISK)
message = "No such disk " + backQuote(move_ttl.destination_name) + " for given storage policy.";
else
message = "No such volume " + backQuote(move_ttl.destination_name) + " for given storage policy.";
throw Exception(message, ErrorCodes::BAD_TTL_EXPRESSION);
}
}
}
}
void MergeTreeData::checkStoragePolicy(const StoragePolicyPtr & new_storage_policy) const
{
const auto old_storage_policy = getStoragePolicy();
old_storage_policy->checkCompatibleWith(new_storage_policy);
}
void MergeTreeData::MergingParams::check(const StorageInMemoryMetadata & metadata) const
{
const auto columns = metadata.getColumns().getAllPhysical();
if (!sign_column.empty() && mode != MergingParams::Collapsing && mode != MergingParams::VersionedCollapsing)
throw Exception("Sign column for MergeTree cannot be specified in modes except Collapsing or VersionedCollapsing.",
ErrorCodes::LOGICAL_ERROR);
if (!version_column.empty() && mode != MergingParams::Replacing && mode != MergingParams::VersionedCollapsing)
throw Exception("Version column for MergeTree cannot be specified in modes except Replacing or VersionedCollapsing.",
ErrorCodes::LOGICAL_ERROR);
if (!columns_to_sum.empty() && mode != MergingParams::Summing)
throw Exception("List of columns to sum for MergeTree cannot be specified in all modes except Summing.",
ErrorCodes::LOGICAL_ERROR);
/// Check that if the sign column is needed, it exists and is of type Int8.
auto check_sign_column = [this, & columns](bool is_optional, const std::string & storage)
{
if (sign_column.empty())
{
if (is_optional)
return;
throw Exception("Logical error: Sign column for storage " + storage + " is empty", ErrorCodes::LOGICAL_ERROR);
}
bool miss_column = true;
for (const auto & column : columns)
{
if (column.name == sign_column)
{
if (!typeid_cast<const DataTypeInt8 *>(column.type.get()))
throw Exception("Sign column (" + sign_column + ") for storage " + storage + " must have type Int8."
" Provided column of type " + column.type->getName() + ".", ErrorCodes::BAD_TYPE_OF_FIELD);
miss_column = false;
break;
}
}
if (miss_column)
throw Exception("Sign column " + sign_column + " does not exist in table declaration.", ErrorCodes::NO_SUCH_COLUMN_IN_TABLE);
};
/// that if the version_column column is needed, it exists and is of unsigned integer type.
auto check_version_column = [this, & columns](bool is_optional, const std::string & storage)
{
if (version_column.empty())
{
if (is_optional)
return;
throw Exception("Logical error: Version column for storage " + storage + " is empty", ErrorCodes::LOGICAL_ERROR);
}
bool miss_column = true;
for (const auto & column : columns)
{
if (column.name == version_column)
{
if (!column.type->canBeUsedAsVersion())
throw Exception("The column " + version_column +
" cannot be used as a version column for storage " + storage +
" because it is of type " + column.type->getName() +
" (must be of an integer type or of type Date or DateTime)", ErrorCodes::BAD_TYPE_OF_FIELD);
miss_column = false;
break;
}
}
if (miss_column)
throw Exception("Version column " + version_column + " does not exist in table declaration.", ErrorCodes::NO_SUCH_COLUMN_IN_TABLE);
};
if (mode == MergingParams::Collapsing)
check_sign_column(false, "CollapsingMergeTree");
if (mode == MergingParams::Summing)
{
/// If columns_to_sum are set, then check that such columns exist.
for (const auto & column_to_sum : columns_to_sum)
{
auto check_column_to_sum_exists = [& column_to_sum](const NameAndTypePair & name_and_type)
{
return column_to_sum == Nested::extractTableName(name_and_type.name);
};
if (columns.end() == std::find_if(columns.begin(), columns.end(), check_column_to_sum_exists))
throw Exception(
"Column " + column_to_sum + " listed in columns to sum does not exist in table declaration.", ErrorCodes::NO_SUCH_COLUMN_IN_TABLE);
}
/// Check that summing columns are not in partition key.
if (metadata.isPartitionKeyDefined())
{
auto partition_key_columns = metadata.getPartitionKey().column_names;
Names names_intersection;
std::set_intersection(columns_to_sum.begin(), columns_to_sum.end(),
partition_key_columns.begin(), partition_key_columns.end(),
std::back_inserter(names_intersection));
if (!names_intersection.empty())
throw Exception("Columns: " + boost::algorithm::join(names_intersection, ", ") +
" listed both in columns to sum and in partition key. That is not allowed.", ErrorCodes::BAD_ARGUMENTS);
}
}
if (mode == MergingParams::Replacing)
check_version_column(true, "ReplacingMergeTree");
if (mode == MergingParams::VersionedCollapsing)
{
check_sign_column(false, "VersionedCollapsingMergeTree");
check_version_column(false, "VersionedCollapsingMergeTree");
}
/// TODO Checks for Graphite mode.
}
String MergeTreeData::MergingParams::getModeName() const
{
switch (mode)
{
case Ordinary: return "";
case Collapsing: return "Collapsing";
case Summing: return "Summing";
case Aggregating: return "Aggregating";
case Replacing: return "Replacing";
case Graphite: return "Graphite";
case VersionedCollapsing: return "VersionedCollapsing";
}
__builtin_unreachable();
}
Int64 MergeTreeData::getMaxBlockNumber() const
{
auto lock = lockParts();
Int64 max_block_num = 0;
for (const DataPartPtr & part : data_parts_by_info)
max_block_num = std::max({max_block_num, part->info.max_block, part->info.mutation});
return max_block_num;
}
void MergeTreeData::loadDataParts(bool skip_sanity_checks)
{
LOG_DEBUG(log, "Loading data parts");
auto metadata_snapshot = getInMemoryMetadataPtr();
const auto settings = getSettings();
std::vector<std::pair<String, DiskPtr>> part_names_with_disks;
MutableDataPartsVector parts_from_wal;
Strings part_file_names;
auto disks = getStoragePolicy()->getDisks();
/// Only check if user did touch storage configuration for this table.
if (!getStoragePolicy()->isDefaultPolicy() && !skip_sanity_checks)
{
/// Check extra parts at different disks, in order to not allow to miss data parts at undefined disks.
std::unordered_set<String> defined_disk_names;
for (const auto & disk_ptr : disks)
defined_disk_names.insert(disk_ptr->getName());
for (const auto & [disk_name, disk] : global_context.getDisksMap())
{
if (defined_disk_names.count(disk_name) == 0 && disk->exists(relative_data_path))
{
for (const auto it = disk->iterateDirectory(relative_data_path); it->isValid(); it->next())
{
MergeTreePartInfo part_info;
if (MergeTreePartInfo::tryParsePartName(it->name(), &part_info, format_version))
throw Exception("Part " + backQuote(it->name()) + " was found on disk " + backQuote(disk_name) + " which is not defined in the storage policy", ErrorCodes::UNKNOWN_DISK);
}
}
}
}
/// Reversed order to load part from low priority disks firstly.
/// Used for keep part on low priority disk if duplication found
for (auto disk_it = disks.rbegin(); disk_it != disks.rend(); ++disk_it)
{
auto disk_ptr = *disk_it;
for (auto it = disk_ptr->iterateDirectory(relative_data_path); it->isValid(); it->next())
{
/// Skip temporary directories.
if (startsWith(it->name(), "tmp"))
continue;
if (!startsWith(it->name(), MergeTreeWriteAheadLog::WAL_FILE_NAME))
part_names_with_disks.emplace_back(it->name(), disk_ptr);
else if (it->name() == MergeTreeWriteAheadLog::DEFAULT_WAL_FILE_NAME && settings->in_memory_parts_enable_wal)
{
/// Create and correctly initialize global WAL object
write_ahead_log = std::make_shared<MergeTreeWriteAheadLog>(*this, disk_ptr, it->name());
for (auto && part : write_ahead_log->restore(metadata_snapshot))
parts_from_wal.push_back(std::move(part));
}
else if (settings->in_memory_parts_enable_wal)
{
MergeTreeWriteAheadLog wal(*this, disk_ptr, it->name());
for (auto && part : wal.restore(metadata_snapshot))
parts_from_wal.push_back(std::move(part));
}
}
}
auto part_lock = lockParts();
data_parts_indexes.clear();
if (part_names_with_disks.empty() && parts_from_wal.empty())
{
LOG_DEBUG(log, "There is no data parts");
return;
}
/// Parallel loading of data parts.
size_t num_threads = std::min(size_t(settings->max_part_loading_threads), part_names_with_disks.size());
std::mutex mutex;
DataPartsVector broken_parts_to_remove;
DataPartsVector broken_parts_to_detach;
size_t suspicious_broken_parts = 0;
std::atomic<bool> has_adaptive_parts = false;
std::atomic<bool> has_non_adaptive_parts = false;
ThreadPool pool(num_threads);
for (size_t i = 0; i < part_names_with_disks.size(); ++i)
{
pool.scheduleOrThrowOnError([&, i]
{
const auto & part_name = part_names_with_disks[i].first;
const auto part_disk_ptr = part_names_with_disks[i].second;
MergeTreePartInfo part_info;
if (!MergeTreePartInfo::tryParsePartName(part_name, &part_info, format_version))
return;
auto single_disk_volume = std::make_shared<SingleDiskVolume>("volume_" + part_name, part_disk_ptr, 0);
auto part = createPart(part_name, part_info, single_disk_volume, part_name);
bool broken = false;
String part_path = relative_data_path + "/" + part_name;
String marker_path = part_path + "/" + IMergeTreeDataPart::DELETE_ON_DESTROY_MARKER_FILE_NAME;
if (part_disk_ptr->exists(marker_path))
{
LOG_WARNING(log, "Detaching stale part {}{}, which should have been deleted after a move. That can only happen after unclean restart of ClickHouse after move of a part having an operation blocking that stale copy of part.", getFullPathOnDisk(part_disk_ptr), part_name);
std::lock_guard loading_lock(mutex);
broken_parts_to_detach.push_back(part);
++suspicious_broken_parts;
return;
}
try
{
part->loadColumnsChecksumsIndexes(require_part_metadata, true);
}
catch (const Exception & e)
{
/// Don't count the part as broken if there is not enough memory to load it.
/// In fact, there can be many similar situations.
/// But it is OK, because there is a safety guard against deleting too many parts.
if (isNotEnoughMemoryErrorCode(e.code()))
throw;
broken = true;
tryLogCurrentException(__PRETTY_FUNCTION__);
}
catch (...)
{
broken = true;
tryLogCurrentException(__PRETTY_FUNCTION__);
}
/// Ignore and possibly delete broken parts that can appear as a result of hard server restart.
if (broken)
{
if (part->info.level == 0)
{
/// It is impossible to restore level 0 parts.
LOG_ERROR(log, "Considering to remove broken part {}{} because it's impossible to repair.", getFullPathOnDisk(part_disk_ptr), part_name);
std::lock_guard loading_lock(mutex);
broken_parts_to_remove.push_back(part);
}
else
{
/// Count the number of parts covered by the broken part. If it is at least two, assume that
/// the broken part was created as a result of merging them and we won't lose data if we
/// delete it.
size_t contained_parts = 0;
LOG_ERROR(log, "Part {}{} is broken. Looking for parts to replace it.", getFullPathOnDisk(part_disk_ptr), part_name);
for (const auto & [contained_name, contained_disk_ptr] : part_names_with_disks)
{
if (contained_name == part_name)
continue;
MergeTreePartInfo contained_part_info;
if (!MergeTreePartInfo::tryParsePartName(contained_name, &contained_part_info, format_version))
continue;
if (part->info.contains(contained_part_info))
{
LOG_ERROR(log, "Found part {}{}", getFullPathOnDisk(contained_disk_ptr), contained_name);
++contained_parts;
}
}
if (contained_parts >= 2)
{
LOG_ERROR(log, "Considering to remove broken part {}{} because it covers at least 2 other parts", getFullPathOnDisk(part_disk_ptr), part_name);
std::lock_guard loading_lock(mutex);
broken_parts_to_remove.push_back(part);
}
else
{
LOG_ERROR(log, "Detaching broken part {}{} because it covers less than 2 parts. You need to resolve this manually", getFullPathOnDisk(part_disk_ptr), part_name);
std::lock_guard loading_lock(mutex);
broken_parts_to_detach.push_back(part);
++suspicious_broken_parts;
}
}
return;
}
if (!part->index_granularity_info.is_adaptive)
has_non_adaptive_parts.store(true, std::memory_order_relaxed);
else
has_adaptive_parts.store(true, std::memory_order_relaxed);
part->modification_time = part_disk_ptr->getLastModified(relative_data_path + part_name).epochTime();
/// Assume that all parts are Committed, covered parts will be detected and marked as Outdated later
part->setState(DataPartState::Committed);
std::lock_guard loading_lock(mutex);
if (!data_parts_indexes.insert(part).second)
throw Exception("Part " + part->name + " already exists", ErrorCodes::DUPLICATE_DATA_PART);
addPartContributionToDataVolume(part);
});
}
pool.wait();
for (auto & part : parts_from_wal)
{
if (getActiveContainingPart(part->info, DataPartState::Committed, part_lock))
continue;
part->modification_time = time(nullptr);
/// Assume that all parts are Committed, covered parts will be detected and marked as Outdated later
part->setState(DataPartState::Committed);
if (!data_parts_indexes.insert(part).second)
throw Exception("Part " + part->name + " already exists", ErrorCodes::DUPLICATE_DATA_PART);
addPartContributionToDataVolume(part);
}
if (has_non_adaptive_parts && has_adaptive_parts && !settings->enable_mixed_granularity_parts)
throw Exception("Table contains parts with adaptive and non adaptive marks, but `setting enable_mixed_granularity_parts` is disabled", ErrorCodes::LOGICAL_ERROR);
has_non_adaptive_index_granularity_parts = has_non_adaptive_parts;
if (suspicious_broken_parts > settings->max_suspicious_broken_parts && !skip_sanity_checks)
throw Exception("Suspiciously many (" + toString(suspicious_broken_parts) + ") broken parts to remove.",
ErrorCodes::TOO_MANY_UNEXPECTED_DATA_PARTS);
for (auto & part : broken_parts_to_remove)
part->remove();
for (auto & part : broken_parts_to_detach)
part->renameToDetached("");
/// Delete from the set of current parts those parts that are covered by another part (those parts that
/// were merged), but that for some reason are still not deleted from the filesystem.
/// Deletion of files will be performed later in the clearOldParts() method.
if (data_parts_indexes.size() >= 2)
{
/// Now all parts are committed, so data_parts_by_state_and_info == committed_parts_range
auto prev_jt = data_parts_by_state_and_info.begin();
auto curr_jt = std::next(prev_jt);
auto deactivate_part = [&] (DataPartIteratorByStateAndInfo it)
{
(*it)->remove_time.store((*it)->modification_time, std::memory_order_relaxed);
modifyPartState(it, DataPartState::Outdated);
removePartContributionToDataVolume(*it);
};
(*prev_jt)->assertState({DataPartState::Committed});
while (curr_jt != data_parts_by_state_and_info.end() && (*curr_jt)->getState() == DataPartState::Committed)
{
/// Don't consider data parts belonging to different partitions.
if ((*curr_jt)->info.partition_id != (*prev_jt)->info.partition_id)
{
++prev_jt;
++curr_jt;
continue;
}
if ((*curr_jt)->contains(**prev_jt))
{
deactivate_part(prev_jt);
prev_jt = curr_jt;
++curr_jt;
}
else if ((*prev_jt)->contains(**curr_jt))
{
auto next = std::next(curr_jt);
deactivate_part(curr_jt);
curr_jt = next;
}
else
{
++prev_jt;
++curr_jt;
}
}
}
calculateColumnSizesImpl();
LOG_DEBUG(log, "Loaded data parts ({} items)", data_parts_indexes.size());
}
/// Is the part directory old.
/// True if its modification time and the modification time of all files inside it is less then threshold.
/// (Only files on the first level of nesting are considered).
static bool isOldPartDirectory(const DiskPtr & disk, const String & directory_path, time_t threshold)
{
if (disk->getLastModified(directory_path).epochTime() >= threshold)
return false;
for (auto it = disk->iterateDirectory(directory_path); it->isValid(); it->next())
if (disk->getLastModified(it->path()).epochTime() >= threshold)
return false;
return true;
}
void MergeTreeData::clearOldTemporaryDirectories(ssize_t custom_directories_lifetime_seconds)
{
/// If the method is already called from another thread, then we don't need to do anything.
std::unique_lock lock(clear_old_temporary_directories_mutex, std::defer_lock);
if (!lock.try_lock())
return;
const auto settings = getSettings();
time_t current_time = time(nullptr);
ssize_t deadline = (custom_directories_lifetime_seconds >= 0)
? current_time - custom_directories_lifetime_seconds
: current_time - settings->temporary_directories_lifetime.totalSeconds();
/// Delete temporary directories older than a day.
for (const auto & [path, disk] : getRelativeDataPathsWithDisks())
{
for (auto it = disk->iterateDirectory(path); it->isValid(); it->next())
{
if (startsWith(it->name(), "tmp_"))
{
try
{
if (disk->isDirectory(it->path()) && isOldPartDirectory(disk, it->path(), deadline))
{
LOG_WARNING(log, "Removing temporary directory {}", fullPath(disk, it->path()));
disk->removeRecursive(it->path());
}
}
catch (const Poco::FileNotFoundException &)
{
/// If the file is already deleted, do nothing.
}
}
}
}
}
MergeTreeData::DataPartsVector MergeTreeData::grabOldParts(bool force)
{
DataPartsVector res;
/// If the method is already called from another thread, then we don't need to do anything.
std::unique_lock lock(grab_old_parts_mutex, std::defer_lock);
if (!lock.try_lock())
return res;
time_t now = time(nullptr);
std::vector<DataPartIteratorByStateAndInfo> parts_to_delete;
{
auto parts_lock = lockParts();
auto outdated_parts_range = getDataPartsStateRange(DataPartState::Outdated);
for (auto it = outdated_parts_range.begin(); it != outdated_parts_range.end(); ++it)
{
const DataPartPtr & part = *it;
auto part_remove_time = part->remove_time.load(std::memory_order_relaxed);
if (part.unique() && /// Grab only parts that are not used by anyone (SELECTs for example).
((part_remove_time < now &&
now - part_remove_time > getSettings()->old_parts_lifetime.totalSeconds()) || force
|| isInMemoryPart(part))) /// Remove in-memory parts immediately to not store excessive data in RAM
{
parts_to_delete.emplace_back(it);
}
}
res.reserve(parts_to_delete.size());
for (const auto & it_to_delete : parts_to_delete)
{
res.emplace_back(*it_to_delete);
modifyPartState(it_to_delete, DataPartState::Deleting);
}
}
if (!res.empty())
LOG_TRACE(log, "Found {} old parts to remove.", res.size());
return res;
}
void MergeTreeData::rollbackDeletingParts(const MergeTreeData::DataPartsVector & parts)
{
auto lock = lockParts();
for (const auto & part : parts)
{
/// We should modify it under data_parts_mutex
part->assertState({DataPartState::Deleting});
modifyPartState(part, DataPartState::Outdated);
}
}
void MergeTreeData::removePartsFinally(const MergeTreeData::DataPartsVector & parts)
{
{
auto lock = lockParts();
/// TODO: use data_parts iterators instead of pointers
for (const auto & part : parts)
{
auto it = data_parts_by_info.find(part->info);
if (it == data_parts_by_info.end())
throw Exception("Deleting data part " + part->name + " doesn't exist", ErrorCodes::LOGICAL_ERROR);
(*it)->assertState({DataPartState::Deleting});
data_parts_indexes.erase(it);
}
}
/// Data parts is still alive (since DataPartsVector holds shared_ptrs) and contain useful metainformation for logging
/// NOTE: There is no need to log parts deletion somewhere else, all deleting parts pass through this function and pass away
auto table_id = getStorageID();
if (auto part_log = global_context.getPartLog(table_id.database_name))
{
PartLogElement part_log_elem;
part_log_elem.event_type = PartLogElement::REMOVE_PART;
part_log_elem.event_time = time(nullptr);
part_log_elem.duration_ms = 0;
part_log_elem.database_name = table_id.database_name;
part_log_elem.table_name = table_id.table_name;
for (const auto & part : parts)
{
part_log_elem.partition_id = part->info.partition_id;
part_log_elem.part_name = part->name;
part_log_elem.bytes_compressed_on_disk = part->getBytesOnDisk();
part_log_elem.rows = part->rows_count;
part_log->add(part_log_elem);
}
}
}
void MergeTreeData::clearOldPartsFromFilesystem(bool force)
{
DataPartsVector parts_to_remove = grabOldParts(force);
clearPartsFromFilesystem(parts_to_remove);
removePartsFinally(parts_to_remove);
}
void MergeTreeData::clearPartsFromFilesystem(const DataPartsVector & parts_to_remove)
{
const auto settings = getSettings();
if (parts_to_remove.size() > 1 && settings->max_part_removal_threads > 1 && parts_to_remove.size() > settings->concurrent_part_removal_threshold)
{
/// Parallel parts removal.
size_t num_threads = std::min(size_t(settings->max_part_removal_threads), parts_to_remove.size());
ThreadPool pool(num_threads);
/// NOTE: Under heavy system load you may get "Cannot schedule a task" from ThreadPool.
for (const DataPartPtr & part : parts_to_remove)
{
pool.scheduleOrThrowOnError([&]
{
LOG_DEBUG(log, "Removing part from filesystem {}", part->name);
part->remove();
});
}
pool.wait();
}
else
{
for (const DataPartPtr & part : parts_to_remove)
{
LOG_DEBUG(log, "Removing part from filesystem {}", part->name);
part->remove();
}
}
}
void MergeTreeData::clearOldWriteAheadLogs()
{
DataPartsVector parts = getDataPartsVector();
std::vector<std::pair<Int64, Int64>> all_block_numbers_on_disk;
std::vector<std::pair<Int64, Int64>> block_numbers_on_disk;
for (const auto & part : parts)
if (part->isStoredOnDisk())
all_block_numbers_on_disk.emplace_back(part->info.min_block, part->info.max_block);
if (all_block_numbers_on_disk.empty())
return;
std::sort(all_block_numbers_on_disk.begin(), all_block_numbers_on_disk.end());
block_numbers_on_disk.push_back(all_block_numbers_on_disk[0]);
for (size_t i = 1; i < all_block_numbers_on_disk.size(); ++i)
{
if (all_block_numbers_on_disk[i].first == all_block_numbers_on_disk[i - 1].second + 1)
block_numbers_on_disk.back().second = all_block_numbers_on_disk[i].second;
else
block_numbers_on_disk.push_back(all_block_numbers_on_disk[i]);
}
auto is_range_on_disk = [&block_numbers_on_disk](Int64 min_block, Int64 max_block)
{
auto lower = std::lower_bound(block_numbers_on_disk.begin(), block_numbers_on_disk.end(), std::make_pair(min_block, Int64(-1L)));
if (lower != block_numbers_on_disk.end() && min_block >= lower->first && max_block <= lower->second)
return true;
if (lower != block_numbers_on_disk.begin())
{
--lower;
if (min_block >= lower->first && max_block <= lower->second)
return true;
}
return false;
};
auto disks = getStoragePolicy()->getDisks();
for (auto disk_it = disks.rbegin(); disk_it != disks.rend(); ++disk_it)
{
auto disk_ptr = *disk_it;
for (auto it = disk_ptr->iterateDirectory(relative_data_path); it->isValid(); it->next())
{
auto min_max_block_number = MergeTreeWriteAheadLog::tryParseMinMaxBlockNumber(it->name());
if (min_max_block_number && is_range_on_disk(min_max_block_number->first, min_max_block_number->second))
{
LOG_DEBUG(log, "Removing from filesystem the outdated WAL file " + it->name());
disk_ptr->removeFile(relative_data_path + it->name());
}
}
}
}
void MergeTreeData::clearEmptyParts()
{
if (!getSettings()->remove_empty_parts)
return;
auto parts = getDataPartsVector();
for (const auto & part : parts)
{
if (part->rows_count == 0)
{
ASTPtr literal = std::make_shared<ASTLiteral>(part->name);
/// If another replica has already started drop, it's ok, no need to throw.
dropPartition(literal, /* detach = */ false, /*drop_part = */ true, global_context, /* throw_if_noop = */ false);
}
}
}
void MergeTreeData::rename(const String & new_table_path, const StorageID & new_table_id)
{
auto disks = getStoragePolicy()->getDisks();
for (const auto & disk : disks)
{
if (disk->exists(new_table_path))
throw Exception{"Target path already exists: " + fullPath(disk, new_table_path), ErrorCodes::DIRECTORY_ALREADY_EXISTS};
}
for (const auto & disk : disks)
{
auto new_table_path_parent = parentPath(new_table_path);
disk->createDirectories(new_table_path_parent);
disk->moveDirectory(relative_data_path, new_table_path);
}
if (!getStorageID().hasUUID())
global_context.dropCaches();
relative_data_path = new_table_path;
renameInMemory(new_table_id);
}
void MergeTreeData::dropAllData()
{
LOG_TRACE(log, "dropAllData: waiting for locks.");
auto lock = lockParts();
LOG_TRACE(log, "dropAllData: removing data from memory.");
DataPartsVector all_parts(data_parts_by_info.begin(), data_parts_by_info.end());
data_parts_indexes.clear();
column_sizes.clear();
/// Tables in atomic databases have UUID and stored in persistent locations.
/// No need to drop caches (that are keyed by filesystem path) because collision is not possible.
if (!getStorageID().hasUUID())
global_context.dropCaches();
LOG_TRACE(log, "dropAllData: removing data from filesystem.");
/// Removing of each data part before recursive removal of directory is to speed-up removal, because there will be less number of syscalls.
clearPartsFromFilesystem(all_parts);
for (const auto & [path, disk] : getRelativeDataPathsWithDisks())
{
try
{
disk->removeRecursive(path);
}
catch (const Poco::FileNotFoundException &)
{
/// If the file is already deleted, log the error message and do nothing.
tryLogCurrentException(__PRETTY_FUNCTION__);
}
}
setDataVolume(0, 0, 0);
LOG_TRACE(log, "dropAllData: done.");
}
void MergeTreeData::dropIfEmpty()
{
LOG_TRACE(log, "dropIfEmpty");
auto lock = lockParts();
if (!data_parts_by_info.empty())
return;
for (const auto & [path, disk] : getRelativeDataPathsWithDisks())
{
/// Non recursive, exception is thrown if there are more files.
disk->removeFile(path + "format_version.txt");
disk->removeDirectory(path + "detached");
disk->removeDirectory(path);
}
}
namespace
{
/// Conversion that is allowed for serializable key (primary key, sorting key).
/// Key should be serialized in the same way after conversion.
/// NOTE: The list is not complete.
bool isSafeForKeyConversion(const IDataType * from, const IDataType * to)
{
if (from->getName() == to->getName())
return true;
/// Enums are serialized in partition key as numbers - so conversion from Enum to number is Ok.
/// But only for types of identical width because they are serialized as binary in minmax index.
/// But not from number to Enum because Enum does not necessarily represents all numbers.
if (const auto * from_enum8 = typeid_cast<const DataTypeEnum8 *>(from))
{
if (const auto * to_enum8 = typeid_cast<const DataTypeEnum8 *>(to))
return to_enum8->contains(*from_enum8);
if (typeid_cast<const DataTypeInt8 *>(to))
return true; // NOLINT
return false;
}
if (const auto * from_enum16 = typeid_cast<const DataTypeEnum16 *>(from))
{
if (const auto * to_enum16 = typeid_cast<const DataTypeEnum16 *>(to))
return to_enum16->contains(*from_enum16);
if (typeid_cast<const DataTypeInt16 *>(to))
return true; // NOLINT
return false;
}
if (const auto * from_lc = typeid_cast<const DataTypeLowCardinality *>(from))
return from_lc->getDictionaryType()->equals(*to);
if (const auto * to_lc = typeid_cast<const DataTypeLowCardinality *>(to))
return to_lc->getDictionaryType()->equals(*from);
return false;
}
/// Special check for alters of VersionedCollapsingMergeTree version column
void checkVersionColumnTypesConversion(const IDataType * old_type, const IDataType * new_type, const String column_name)
{
/// Check new type can be used as version
if (!new_type->canBeUsedAsVersion())
throw Exception("Cannot alter version column " + backQuoteIfNeed(column_name) +
" to type " + new_type->getName() +
" because version column must be of an integer type or of type Date or DateTime"
, ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
auto which_new_type = WhichDataType(new_type);
auto which_old_type = WhichDataType(old_type);
/// Check alter to different sign or float -> int and so on
if ((which_old_type.isInt() && !which_new_type.isInt())
|| (which_old_type.isUInt() && !which_new_type.isUInt())
|| (which_old_type.isDate() && !which_new_type.isDate())
|| (which_old_type.isDateTime() && !which_new_type.isDateTime())
|| (which_old_type.isFloat() && !which_new_type.isFloat()))
{
throw Exception("Cannot alter version column " + backQuoteIfNeed(column_name) +
" from type " + old_type->getName() +
" to type " + new_type->getName() + " because new type will change sort order of version column." +
" The only possible conversion is expansion of the number of bytes of the current type."
, ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
}
/// Check alter to smaller size: UInt64 -> UInt32 and so on
if (new_type->getSizeOfValueInMemory() < old_type->getSizeOfValueInMemory())
{
throw Exception("Cannot alter version column " + backQuoteIfNeed(column_name) +
" from type " + old_type->getName() +
" to type " + new_type->getName() + " because new type is smaller than current in the number of bytes." +
" The only possible conversion is expansion of the number of bytes of the current type."
, ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
}
}
}
void MergeTreeData::checkAlterIsPossible(const AlterCommands & commands, const Settings & settings) const
{
/// Check that needed transformations can be applied to the list of columns without considering type conversions.
StorageInMemoryMetadata new_metadata = getInMemoryMetadata();
StorageInMemoryMetadata old_metadata = getInMemoryMetadata();
if (!settings.allow_non_metadata_alters)
{
auto mutation_commands = commands.getMutationCommands(new_metadata, settings.materialize_ttl_after_modify, global_context);
if (!mutation_commands.empty())
throw Exception(ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN, "The following alter commands: '{}' will modify data on disk, but setting `allow_non_metadata_alters` is disabled", queryToString(mutation_commands.ast()));
}
commands.apply(new_metadata, global_context);
/// Set of columns that shouldn't be altered.
NameSet columns_alter_type_forbidden;
/// Primary key columns can be ALTERed only if they are used in the key as-is
/// (and not as a part of some expression) and if the ALTER only affects column metadata.
NameSet columns_alter_type_metadata_only;
/// Columns to check that the type change is safe for partition key.
NameSet columns_alter_type_check_safe_for_partition;
if (old_metadata.hasPartitionKey())
{
/// Forbid altering columns inside partition key expressions because it can change partition ID format.
auto partition_key_expr = old_metadata.getPartitionKey().expression;
for (const auto & action : partition_key_expr->getActions())
{
for (const auto * child : action.node->children)
columns_alter_type_forbidden.insert(child->result_name);
}
/// But allow to alter columns without expressions under certain condition.
for (const String & col : partition_key_expr->getRequiredColumns())
columns_alter_type_check_safe_for_partition.insert(col);
}
for (const auto & index : old_metadata.getSecondaryIndices())
{
for (const String & col : index.expression->getRequiredColumns())
columns_alter_type_forbidden.insert(col);
}
if (old_metadata.hasSortingKey())
{
auto sorting_key_expr = old_metadata.getSortingKey().expression;
for (const auto & action : sorting_key_expr->getActions())
{
for (const auto * child : action.node->children)
columns_alter_type_forbidden.insert(child->result_name);
}
for (const String & col : sorting_key_expr->getRequiredColumns())
columns_alter_type_metadata_only.insert(col);
/// We don't process sample_by_ast separately because it must be among the primary key columns
/// and we don't process primary_key_expr separately because it is a prefix of sorting_key_expr.
}
if (!merging_params.sign_column.empty())
columns_alter_type_forbidden.insert(merging_params.sign_column);
/// All of the above.
NameSet columns_in_keys;
columns_in_keys.insert(columns_alter_type_forbidden.begin(), columns_alter_type_forbidden.end());
columns_in_keys.insert(columns_alter_type_metadata_only.begin(), columns_alter_type_metadata_only.end());
columns_in_keys.insert(columns_alter_type_check_safe_for_partition.begin(), columns_alter_type_check_safe_for_partition.end());
NameSet dropped_columns;
std::map<String, const IDataType *> old_types;
for (const auto & column : old_metadata.getColumns().getAllPhysical())
old_types.emplace(column.name, column.type.get());
NamesAndTypesList columns_to_check_conversion;
for (const AlterCommand & command : commands)
{
/// Just validate partition expression
if (command.partition)
{
getPartitionIDFromQuery(command.partition, global_context);
}
if (command.column_name == merging_params.version_column)
{
/// Some type changes for version column is allowed despite it's a part of sorting key
if (command.type == AlterCommand::MODIFY_COLUMN)
{
const IDataType * new_type = command.data_type.get();
const IDataType * old_type = old_types[command.column_name];
checkVersionColumnTypesConversion(old_type, new_type, command.column_name);
/// No other checks required
continue;
}
else if (command.type == AlterCommand::DROP_COLUMN)
{
throw Exception(
"Trying to ALTER DROP version " + backQuoteIfNeed(command.column_name) + " column",
ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
}
else if (command.type == AlterCommand::RENAME_COLUMN)
{
throw Exception(
"Trying to ALTER RENAME version " + backQuoteIfNeed(command.column_name) + " column",
ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
}
}
if (command.type == AlterCommand::MODIFY_ORDER_BY && !is_custom_partitioned)
{
throw Exception(
"ALTER MODIFY ORDER BY is not supported for default-partitioned tables created with the old syntax",
ErrorCodes::BAD_ARGUMENTS);
}
if (command.type == AlterCommand::MODIFY_TTL && !is_custom_partitioned)
{
throw Exception(
"ALTER MODIFY TTL is not supported for default-partitioned tables created with the old syntax",
ErrorCodes::BAD_ARGUMENTS);
}
if (command.type == AlterCommand::MODIFY_SAMPLE_BY)
{
if (!is_custom_partitioned)
throw Exception(
"ALTER MODIFY SAMPLE BY is not supported for default-partitioned tables created with the old syntax",
ErrorCodes::BAD_ARGUMENTS);
checkSampleExpression(new_metadata, getSettings()->compatibility_allow_sampling_expression_not_in_primary_key);
}
if (command.type == AlterCommand::ADD_INDEX && !is_custom_partitioned)
{
throw Exception(
"ALTER ADD INDEX is not supported for tables with the old syntax",
ErrorCodes::BAD_ARGUMENTS);
}
if (command.type == AlterCommand::RENAME_COLUMN)
{
if (columns_in_keys.count(command.column_name))
{
throw Exception(
"Trying to ALTER RENAME key " + backQuoteIfNeed(command.column_name) + " column which is a part of key expression",
ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
}
}
else if (command.type == AlterCommand::DROP_COLUMN)
{
if (columns_in_keys.count(command.column_name))
{
throw Exception(
"Trying to ALTER DROP key " + backQuoteIfNeed(command.column_name) + " column which is a part of key expression",
ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
}
dropped_columns.emplace(command.column_name);
}
else if (command.isRequireMutationStage(getInMemoryMetadata()))
{
/// This alter will override data on disk. Let's check that it doesn't
/// modify immutable column.
if (columns_alter_type_forbidden.count(command.column_name))
throw Exception("ALTER of key column " + backQuoteIfNeed(command.column_name) + " is forbidden",
ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
if (command.type == AlterCommand::MODIFY_COLUMN)
{
if (columns_alter_type_check_safe_for_partition.count(command.column_name))
{
auto it = old_types.find(command.column_name);
assert(it != old_types.end());
if (!isSafeForKeyConversion(it->second, command.data_type.get()))
throw Exception("ALTER of partition key column " + backQuoteIfNeed(command.column_name) + " from type "
+ it->second->getName() + " to type " + command.data_type->getName()
+ " is not safe because it can change the representation of partition key",
ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
}
if (columns_alter_type_metadata_only.count(command.column_name))
{
auto it = old_types.find(command.column_name);
assert(it != old_types.end());
if (!isSafeForKeyConversion(it->second, command.data_type.get()))
throw Exception("ALTER of key column " + backQuoteIfNeed(command.column_name) + " from type "
+ it->second->getName() + " to type " + command.data_type->getName()
+ " is not safe because it can change the representation of primary key",
ErrorCodes::ALTER_OF_COLUMN_IS_FORBIDDEN);
}
if (old_metadata.getColumns().has(command.column_name))
{
columns_to_check_conversion.push_back(
new_metadata.getColumns().getPhysical(command.column_name));
}
}
}
}
checkProperties(new_metadata, old_metadata);
checkTTLExpressions(new_metadata, old_metadata);
if (!columns_to_check_conversion.empty())
{
auto old_header = old_metadata.getSampleBlock();
performRequiredConversions(old_header, columns_to_check_conversion, global_context);
}
if (old_metadata.hasSettingsChanges())
{
const auto current_changes = old_metadata.getSettingsChanges()->as<const ASTSetQuery &>().changes;
const auto & new_changes = new_metadata.settings_changes->as<const ASTSetQuery &>().changes;
for (const auto & changed_setting : new_changes)
{
const auto & setting_name = changed_setting.name;
const auto & new_value = changed_setting.value;
MergeTreeSettings::checkCanSet(setting_name, new_value);
const Field * current_value = current_changes.tryGet(setting_name);
if ((!current_value || *current_value != new_value)
&& MergeTreeSettings::isReadonlySetting(setting_name))
{
throw Exception{"Setting '" + setting_name + "' is readonly for storage '" + getName() + "'",
ErrorCodes::READONLY_SETTING};
}
if (!current_value && MergeTreeSettings::isPartFormatSetting(setting_name))
{
MergeTreeSettings copy = *getSettings();
copy.applyChange(changed_setting);
String reason;
if (!canUsePolymorphicParts(copy, &reason) && !reason.empty())
throw Exception("Can't change settings. Reason: " + reason, ErrorCodes::NOT_IMPLEMENTED);
}
if (setting_name == "storage_policy")
checkStoragePolicy(global_context.getStoragePolicy(new_value.safeGet<String>()));
}
}
for (const auto & part : getDataPartsVector())
{
bool at_least_one_column_rest = false;
for (const auto & column : part->getColumns())
{
if (!dropped_columns.count(column.name))
{
at_least_one_column_rest = true;
break;
}
}
if (!at_least_one_column_rest)
{
std::string postfix;
if (dropped_columns.size() > 1)
postfix = "s";
throw Exception(ErrorCodes::BAD_ARGUMENTS,
"Cannot drop or clear column{} '{}', because all columns in part '{}' will be removed from disk. Empty parts are not allowed", postfix, boost::algorithm::join(dropped_columns, ", "), part->name);
}
}
}
void MergeTreeData::checkMutationIsPossible(const MutationCommands & /*commands*/, const Settings & /*settings*/) const
{
/// Some validation will be added
}
MergeTreeDataPartType MergeTreeData::choosePartType(size_t bytes_uncompressed, size_t rows_count) const
{
const auto settings = getSettings();
if (!canUsePolymorphicParts(*settings))
return MergeTreeDataPartType::WIDE;
if (bytes_uncompressed < settings->min_bytes_for_compact_part || rows_count < settings->min_rows_for_compact_part)
return MergeTreeDataPartType::IN_MEMORY;
if (bytes_uncompressed < settings->min_bytes_for_wide_part || rows_count < settings->min_rows_for_wide_part)
return MergeTreeDataPartType::COMPACT;
return MergeTreeDataPartType::WIDE;
}
MergeTreeDataPartType MergeTreeData::choosePartTypeOnDisk(size_t bytes_uncompressed, size_t rows_count) const
{
const auto settings = getSettings();
if (!canUsePolymorphicParts(*settings))
return MergeTreeDataPartType::WIDE;
if (bytes_uncompressed < settings->min_bytes_for_wide_part || rows_count < settings->min_rows_for_wide_part)
return MergeTreeDataPartType::COMPACT;
return MergeTreeDataPartType::WIDE;
}
MergeTreeData::MutableDataPartPtr MergeTreeData::createPart(const String & name,
MergeTreeDataPartType type, const MergeTreePartInfo & part_info,
const VolumePtr & volume, const String & relative_path) const
{
if (type == MergeTreeDataPartType::COMPACT)
return std::make_shared<MergeTreeDataPartCompact>(*this, name, part_info, volume, relative_path);
else if (type == MergeTreeDataPartType::WIDE)
return std::make_shared<MergeTreeDataPartWide>(*this, name, part_info, volume, relative_path);
else if (type == MergeTreeDataPartType::IN_MEMORY)
return std::make_shared<MergeTreeDataPartInMemory>(*this, name, part_info, volume, relative_path);
else
throw Exception("Unknown type of part " + relative_path, ErrorCodes::UNKNOWN_PART_TYPE);
}
static MergeTreeDataPartType getPartTypeFromMarkExtension(const String & mrk_ext)
{
if (mrk_ext == getNonAdaptiveMrkExtension())
return MergeTreeDataPartType::WIDE;
if (mrk_ext == getAdaptiveMrkExtension(MergeTreeDataPartType::WIDE))
return MergeTreeDataPartType::WIDE;
if (mrk_ext == getAdaptiveMrkExtension(MergeTreeDataPartType::COMPACT))
return MergeTreeDataPartType::COMPACT;
throw Exception("Can't determine part type, because of unknown mark extension " + mrk_ext, ErrorCodes::UNKNOWN_PART_TYPE);
}
MergeTreeData::MutableDataPartPtr MergeTreeData::createPart(
const String & name, const VolumePtr & volume, const String & relative_path) const
{
return createPart(name, MergeTreePartInfo::fromPartName(name, format_version), volume, relative_path);
}
MergeTreeData::MutableDataPartPtr MergeTreeData::createPart(
const String & name, const MergeTreePartInfo & part_info,
const VolumePtr & volume, const String & relative_path) const
{
MergeTreeDataPartType type;
auto full_path = relative_data_path + relative_path + "/";
auto mrk_ext = MergeTreeIndexGranularityInfo::getMarksExtensionFromFilesystem(volume->getDisk(), full_path);
if (mrk_ext)
type = getPartTypeFromMarkExtension(*mrk_ext);
else
{
/// Didn't find any mark file, suppose that part is empty.
type = choosePartTypeOnDisk(0, 0);
}
return createPart(name, type, part_info, volume, relative_path);
}
void MergeTreeData::changeSettings(
const ASTPtr & new_settings,
TableLockHolder & /* table_lock_holder */)
{
if (new_settings)
{
bool has_storage_policy_changed = false;
const auto & new_changes = new_settings->as<const ASTSetQuery &>().changes;
for (const auto & change : new_changes)
{
if (change.name == "storage_policy")
{
StoragePolicyPtr new_storage_policy = global_context.getStoragePolicy(change.value.safeGet<String>());
StoragePolicyPtr old_storage_policy = getStoragePolicy();
/// StoragePolicy of different version or name is guaranteed to have different pointer
if (new_storage_policy != old_storage_policy)
{
checkStoragePolicy(new_storage_policy);
std::unordered_set<String> all_diff_disk_names;
for (const auto & disk : new_storage_policy->getDisks())
all_diff_disk_names.insert(disk->getName());
for (const auto & disk : old_storage_policy->getDisks())
all_diff_disk_names.erase(disk->getName());
for (const String & disk_name : all_diff_disk_names)
{
auto disk = new_storage_policy->getDiskByName(disk_name);
if (disk->exists(relative_data_path))
throw Exception("New storage policy contain disks which already contain data of a table with the same name", ErrorCodes::LOGICAL_ERROR);
}
for (const String & disk_name : all_diff_disk_names)
{
auto disk = new_storage_policy->getDiskByName(disk_name);
disk->createDirectories(relative_data_path);
disk->createDirectories(relative_data_path + "detached");
}
/// FIXME how would that be done while reloading configuration???
has_storage_policy_changed = true;
}
}
}
MergeTreeSettings copy = *getSettings();
copy.applyChanges(new_changes);
copy.sanityCheck(global_context.getSettingsRef());
storage_settings.set(std::make_unique<const MergeTreeSettings>(copy));
StorageInMemoryMetadata new_metadata = getInMemoryMetadata();
new_metadata.setSettingsChanges(new_settings);
setInMemoryMetadata(new_metadata);
if (has_storage_policy_changed)
startBackgroundMovesIfNeeded();
}
}
PartitionCommandsResultInfo MergeTreeData::freezeAll(const String & with_name, const StorageMetadataPtr & metadata_snapshot, const Context & context, TableLockHolder &)
{
return freezePartitionsByMatcher([] (const DataPartPtr &) { return true; }, metadata_snapshot, with_name, context);
}
void MergeTreeData::PartsTemporaryRename::addPart(const String & old_name, const String & new_name)
{
old_and_new_names.push_back({old_name, new_name});
for (const auto & [path, disk] : storage.getRelativeDataPathsWithDisks())
{
for (auto it = disk->iterateDirectory(path + source_dir); it->isValid(); it->next())
{
if (it->name() == old_name)
{
old_part_name_to_path_and_disk[old_name] = {path, disk};
break;
}
}
}
}
void MergeTreeData::PartsTemporaryRename::tryRenameAll()
{
renamed = true;
for (size_t i = 0; i < old_and_new_names.size(); ++i)
{
try
{
const auto & [old_name, new_name] = old_and_new_names[i];
if (old_name.empty() || new_name.empty())
throw DB::Exception("Empty part name. Most likely it's a bug.", ErrorCodes::INCORRECT_FILE_NAME);
const auto & [path, disk] = old_part_name_to_path_and_disk[old_name];
const auto full_path = path + source_dir; /// for old_name
disk->moveFile(full_path + old_name, full_path + new_name);
}
catch (...)
{
old_and_new_names.resize(i);
LOG_WARNING(storage.log, "Cannot rename parts to perform operation on them: {}", getCurrentExceptionMessage(false));
throw;
}
}
}
MergeTreeData::PartsTemporaryRename::~PartsTemporaryRename()
{
// TODO what if server had crashed before this destructor was called?
if (!renamed)
return;
for (const auto & [old_name, new_name] : old_and_new_names)
{
if (old_name.empty())
continue;
try
{
const auto & [path, disk] = old_part_name_to_path_and_disk[old_name];
const auto full_path = path + source_dir; /// for old_name
disk->moveFile(full_path + new_name, full_path + old_name);
}
catch (...)
{
tryLogCurrentException(__PRETTY_FUNCTION__);
}
}
}
MergeTreeData::DataPartsVector MergeTreeData::getActivePartsToReplace(
const MergeTreePartInfo & new_part_info,
const String & new_part_name,
DataPartPtr & out_covering_part,
DataPartsLock & /* data_parts_lock */) const
{
/// Parts contained in the part are consecutive in data_parts, intersecting the insertion place for the part itself.
auto it_middle = data_parts_by_state_and_info.lower_bound(DataPartStateAndInfo{DataPartState::Committed, new_part_info});
auto committed_parts_range = getDataPartsStateRange(DataPartState::Committed);
/// Go to the left.
DataPartIteratorByStateAndInfo begin = it_middle;
while (begin != committed_parts_range.begin())
{
auto prev = std::prev(begin);
if (!new_part_info.contains((*prev)->info))
{
if ((*prev)->info.contains(new_part_info))
{
out_covering_part = *prev;
return {};
}
if (!new_part_info.isDisjoint((*prev)->info))
throw Exception("Part " + new_part_name + " intersects previous part " + (*prev)->getNameWithState() +
". It is a bug.", ErrorCodes::LOGICAL_ERROR);
break;
}
begin = prev;
}
/// Go to the right.
DataPartIteratorByStateAndInfo end = it_middle;
while (end != committed_parts_range.end())
{
if ((*end)->info == new_part_info)
throw Exception("Unexpected duplicate part " + (*end)->getNameWithState() + ". It is a bug.", ErrorCodes::LOGICAL_ERROR);
if (!new_part_info.contains((*end)->info))
{
if ((*end)->info.contains(new_part_info))
{
out_covering_part = *end;
return {};
}
if (!new_part_info.isDisjoint((*end)->info))
throw Exception("Part " + new_part_name + " intersects next part " + (*end)->getNameWithState() +
". It is a bug.", ErrorCodes::LOGICAL_ERROR);
break;
}
++end;
}
return DataPartsVector{begin, end};
}
bool MergeTreeData::renameTempPartAndAdd(MutableDataPartPtr & part, SimpleIncrement * increment, Transaction * out_transaction)
{
if (out_transaction && &out_transaction->data != this)
throw Exception("MergeTreeData::Transaction for one table cannot be used with another. It is a bug.",
ErrorCodes::LOGICAL_ERROR);
DataPartsVector covered_parts;
{
auto lock = lockParts();
if (!renameTempPartAndReplace(part, increment, out_transaction, lock, &covered_parts))
return false;
}
if (!covered_parts.empty())
throw Exception("Added part " + part->name + " covers " + toString(covered_parts.size())
+ " existing part(s) (including " + covered_parts[0]->name + ")", ErrorCodes::LOGICAL_ERROR);
return true;
}
bool MergeTreeData::renameTempPartAndReplace(
MutableDataPartPtr & part, SimpleIncrement * increment, Transaction * out_transaction,
std::unique_lock<std::mutex> & lock, DataPartsVector * out_covered_parts)
{
if (out_transaction && &out_transaction->data != this)
throw Exception("MergeTreeData::Transaction for one table cannot be used with another. It is a bug.",
ErrorCodes::LOGICAL_ERROR);
part->assertState({DataPartState::Temporary});
MergeTreePartInfo part_info = part->info;
String part_name;
if (DataPartPtr existing_part_in_partition = getAnyPartInPartition(part->info.partition_id, lock))
{
if (part->partition.value != existing_part_in_partition->partition.value)
throw Exception(
"Partition value mismatch between two parts with the same partition ID. Existing part: "
+ existing_part_in_partition->name + ", newly added part: " + part->name,
ErrorCodes::CORRUPTED_DATA);
}
/** It is important that obtaining new block number and adding that block to parts set is done atomically.
* Otherwise there is race condition - merge of blocks could happen in interval that doesn't yet contain new part.
*/
if (increment)
{
part_info.min_block = part_info.max_block = increment->get();
part_info.mutation = 0; /// it's equal to min_block by default
part_name = part->getNewName(part_info);
}
else /// Parts from ReplicatedMergeTree already have names
part_name = part->name;
LOG_TRACE(log, "Renaming temporary part {} to {}.", part->relative_path, part_name);
auto it_duplicate = data_parts_by_info.find(part_info);
if (it_duplicate != data_parts_by_info.end())
{
String message = "Part " + (*it_duplicate)->getNameWithState() + " already exists";
if ((*it_duplicate)->checkState({DataPartState::Outdated, DataPartState::Deleting}))
throw Exception(message + ", but it will be deleted soon", ErrorCodes::PART_IS_TEMPORARILY_LOCKED);
throw Exception(message, ErrorCodes::DUPLICATE_DATA_PART);
}
DataPartPtr covering_part;
DataPartsVector covered_parts = getActivePartsToReplace(part_info, part_name, covering_part, lock);
DataPartsVector covered_parts_in_memory;
if (covering_part)
{
LOG_WARNING(log, "Tried to add obsolete part {} covered by {}", part_name, covering_part->getNameWithState());
return false;
}
/// All checks are passed. Now we can rename the part on disk.
/// So, we maintain invariant: if a non-temporary part in filesystem then it is in data_parts
///
/// If out_transaction is null, we commit the part to the active set immediately, else add it to the transaction.
part->name = part_name;
part->info = part_info;
part->is_temp = false;
part->setState(DataPartState::PreCommitted);
part->renameTo(part_name, true);
auto part_it = data_parts_indexes.insert(part).first;
if (out_transaction)
{
out_transaction->precommitted_parts.insert(part);
}
else
{
size_t reduce_bytes = 0;
size_t reduce_rows = 0;
size_t reduce_parts = 0;
auto current_time = time(nullptr);
for (const DataPartPtr & covered_part : covered_parts)
{
covered_part->remove_time.store(current_time, std::memory_order_relaxed);
modifyPartState(covered_part, DataPartState::Outdated);
removePartContributionToColumnSizes(covered_part);
reduce_bytes += covered_part->getBytesOnDisk();
reduce_rows += covered_part->rows_count;
++reduce_parts;
}
decreaseDataVolume(reduce_bytes, reduce_rows, reduce_parts);
modifyPartState(part_it, DataPartState::Committed);
addPartContributionToColumnSizes(part);
addPartContributionToDataVolume(part);
}
auto part_in_memory = asInMemoryPart(part);
if (part_in_memory && getSettings()->in_memory_parts_enable_wal)
{
auto wal = getWriteAheadLog();
wal->addPart(part_in_memory);
}
if (out_covered_parts)
{
for (DataPartPtr & covered_part : covered_parts)
out_covered_parts->emplace_back(std::move(covered_part));
}
return true;
}
MergeTreeData::DataPartsVector MergeTreeData::renameTempPartAndReplace(
MutableDataPartPtr & part, SimpleIncrement * increment, Transaction * out_transaction)
{
if (out_transaction && &out_transaction->data != this)
throw Exception("MergeTreeData::Transaction for one table cannot be used with another. It is a bug.",
ErrorCodes::LOGICAL_ERROR);
DataPartsVector covered_parts;
{
auto lock = lockParts();
renameTempPartAndReplace(part, increment, out_transaction, lock, &covered_parts);
}
return covered_parts;
}
void MergeTreeData::removePartsFromWorkingSet(const MergeTreeData::DataPartsVector & remove, bool clear_without_timeout, DataPartsLock & /*acquired_lock*/)
{
auto remove_time = clear_without_timeout ? 0 : time(nullptr);
for (const DataPartPtr & part : remove)
{
if (part->getState() == IMergeTreeDataPart::State::Committed)
{
removePartContributionToColumnSizes(part);
removePartContributionToDataVolume(part);
}
if (part->getState() == IMergeTreeDataPart::State::Committed || clear_without_timeout)
part->remove_time.store(remove_time, std::memory_order_relaxed);
if (part->getState() != IMergeTreeDataPart::State::Outdated)
modifyPartState(part, IMergeTreeDataPart::State::Outdated);
if (isInMemoryPart(part) && getSettings()->in_memory_parts_enable_wal)
getWriteAheadLog()->dropPart(part->name);
}
}
void MergeTreeData::removePartsFromWorkingSetImmediatelyAndSetTemporaryState(const DataPartsVector & remove)
{
auto lock = lockParts();
for (const auto & part : remove)
{
auto it_part = data_parts_by_info.find(part->info);
if (it_part == data_parts_by_info.end())
throw Exception("Part " + part->getNameWithState() + " not found in data_parts", ErrorCodes::LOGICAL_ERROR);
modifyPartState(part, IMergeTreeDataPart::State::Temporary);
/// Erase immediately
data_parts_indexes.erase(it_part);
}
}
void MergeTreeData::removePartsFromWorkingSet(const DataPartsVector & remove, bool clear_without_timeout, DataPartsLock * acquired_lock)
{
auto lock = (acquired_lock) ? DataPartsLock() : lockParts();
for (const auto & part : remove)
{
if (!data_parts_by_info.count(part->info))
throw Exception("Part " + part->getNameWithState() + " not found in data_parts", ErrorCodes::LOGICAL_ERROR);
part->assertState({DataPartState::PreCommitted, DataPartState::Committed, DataPartState::Outdated});
}
removePartsFromWorkingSet(remove, clear_without_timeout, lock);
}
MergeTreeData::DataPartsVector MergeTreeData::removePartsInRangeFromWorkingSet(const MergeTreePartInfo & drop_range, bool clear_without_timeout,
bool skip_intersecting_parts, DataPartsLock & lock)
{
DataPartsVector parts_to_remove;
if (drop_range.min_block > drop_range.max_block)
return parts_to_remove;
auto partition_range = getDataPartsPartitionRange(drop_range.partition_id);
for (const DataPartPtr & part : partition_range)
{
if (part->info.partition_id != drop_range.partition_id)
throw Exception("Unexpected partition_id of part " + part->name + ". This is a bug.", ErrorCodes::LOGICAL_ERROR);
if (part->info.min_block < drop_range.min_block)
{
if (drop_range.min_block <= part->info.max_block)
{
/// Intersect left border
String error = "Unexpected merged part " + part->name + " intersecting drop range " + drop_range.getPartName();
if (!skip_intersecting_parts)
throw Exception(error, ErrorCodes::LOGICAL_ERROR);
LOG_WARNING(log, error);
}
continue;
}
/// Stop on new parts
if (part->info.min_block > drop_range.max_block)
break;
if (part->info.min_block <= drop_range.max_block && drop_range.max_block < part->info.max_block)
{
/// Intersect right border
String error = "Unexpected merged part " + part->name + " intersecting drop range " + drop_range.getPartName();
if (!skip_intersecting_parts)
throw Exception(error, ErrorCodes::LOGICAL_ERROR);
LOG_WARNING(log, error);
continue;
}
if (part->getState() != DataPartState::Deleting)
parts_to_remove.emplace_back(part);
}
removePartsFromWorkingSet(parts_to_remove, clear_without_timeout, lock);
return parts_to_remove;
}
void MergeTreeData::forgetPartAndMoveToDetached(const MergeTreeData::DataPartPtr & part_to_detach, const String & prefix, bool
restore_covered)
{
LOG_INFO(log, "Renaming {} to {}{} and forgiving it.", part_to_detach->relative_path, prefix, part_to_detach->name);
auto lock = lockParts();
auto it_part = data_parts_by_info.find(part_to_detach->info);
if (it_part == data_parts_by_info.end())
throw Exception("No such data part " + part_to_detach->getNameWithState(), ErrorCodes::NO_SUCH_DATA_PART);
/// What if part_to_detach is a reference to *it_part? Make a new owner just in case.
DataPartPtr part = *it_part;
if (part->getState() == DataPartState::Committed)
{
removePartContributionToDataVolume(part);
removePartContributionToColumnSizes(part);
}
modifyPartState(it_part, DataPartState::Deleting);
part->renameToDetached(prefix);
data_parts_indexes.erase(it_part);
if (restore_covered && part->info.level == 0)
{
LOG_WARNING(log, "Will not recover parts covered by zero-level part {}", part->name);
return;
}
if (restore_covered)
{
Strings restored;
bool error = false;
String error_parts;
Int64 pos = part->info.min_block;
auto is_appropriate_state = [] (DataPartState state)
{
return state == DataPartState::Committed || state == DataPartState::Outdated;
};
auto update_error = [&] (DataPartIteratorByInfo it)
{
error = true;
error_parts += (*it)->getNameWithState() + " ";
};
auto it_middle = data_parts_by_info.lower_bound(part->info);
/// Restore the leftmost part covered by the part
if (it_middle != data_parts_by_info.begin())
{
auto it = std::prev(it_middle);
if (part->contains(**it) && is_appropriate_state((*it)->getState()))
{
/// Maybe, we must consider part level somehow
if ((*it)->info.min_block != part->info.min_block)
update_error(it);
if ((*it)->getState() != DataPartState::Committed)
{
addPartContributionToColumnSizes(*it);
addPartContributionToDataVolume(*it);
modifyPartState(it, DataPartState::Committed); // iterator is not invalidated here
}
pos = (*it)->info.max_block + 1;
restored.push_back((*it)->name);
}
else
update_error(it);
}
else
error = true;
/// Restore "right" parts
for (auto it = it_middle; it != data_parts_by_info.end() && part->contains(**it); ++it)
{
if ((*it)->info.min_block < pos)
continue;
if (!is_appropriate_state((*it)->getState()))
{
update_error(it);
continue;
}
if ((*it)->info.min_block > pos)
update_error(it);
if ((*it)->getState() != DataPartState::Committed)
{
addPartContributionToColumnSizes(*it);
addPartContributionToDataVolume(*it);
modifyPartState(it, DataPartState::Committed);
}
pos = (*it)->info.max_block + 1;
restored.push_back((*it)->name);
}
if (pos != part->info.max_block + 1)
error = true;
for (const String & name : restored)
{
LOG_INFO(log, "Activated part {}", name);
}
if (error)
{
LOG_ERROR(log, "The set of parts restored in place of {} looks incomplete. There might or might not be a data loss.{}", part->name, (error_parts.empty() ? "" : " Suspicious parts: " + error_parts));
}
}
}
void MergeTreeData::tryRemovePartImmediately(DataPartPtr && part)
{
DataPartPtr part_to_delete;
{
auto lock = lockParts();
LOG_TRACE(log, "Trying to immediately remove part {}", part->getNameWithState());
auto it = data_parts_by_info.find(part->info);
if (it == data_parts_by_info.end() || (*it).get() != part.get())
throw Exception("Part " + part->name + " doesn't exist", ErrorCodes::LOGICAL_ERROR);
part.reset();
if (!((*it)->getState() == DataPartState::Outdated && it->unique()))
return;
modifyPartState(it, DataPartState::Deleting);
part_to_delete = *it;
}
try
{
part_to_delete->remove();
}
catch (...)
{
rollbackDeletingParts({part_to_delete});
throw;
}
removePartsFinally({part_to_delete});
LOG_TRACE(log, "Removed part {}", part_to_delete->name);
}
size_t MergeTreeData::getTotalActiveSizeInBytes() const
{
return total_active_size_bytes.load(std::memory_order_acquire);
}
size_t MergeTreeData::getTotalActiveSizeInRows() const
{
return total_active_size_rows.load(std::memory_order_acquire);
}
size_t MergeTreeData::getPartsCount() const
{
return total_active_size_parts.load(std::memory_order_acquire);
}
size_t MergeTreeData::getMaxPartsCountForPartitionWithState(DataPartState state) const
{
auto lock = lockParts();
size_t res = 0;
size_t cur_count = 0;
const String * cur_partition_id = nullptr;
for (const auto & part : getDataPartsStateRange(state))
{
if (cur_partition_id && part->info.partition_id == *cur_partition_id)
{
++cur_count;
}
else
{
cur_partition_id = &part->info.partition_id;
cur_count = 1;
}
res = std::max(res, cur_count);
}
return res;
}
size_t MergeTreeData::getMaxPartsCountForPartition() const
{
return getMaxPartsCountForPartitionWithState(DataPartState::Committed);
}
size_t MergeTreeData::getMaxInactivePartsCountForPartition() const
{
return getMaxPartsCountForPartitionWithState(DataPartState::Outdated);
}
std::optional<Int64> MergeTreeData::getMinPartDataVersion() const
{
auto lock = lockParts();
std::optional<Int64> result;
for (const auto & part : getDataPartsStateRange(DataPartState::Committed))
{
if (!result || *result > part->info.getDataVersion())
result = part->info.getDataVersion();
}
return result;
}
void MergeTreeData::delayInsertOrThrowIfNeeded(Poco::Event * until) const
{
const auto settings = getSettings();
const size_t parts_count_in_total = getPartsCount();
if (parts_count_in_total >= settings->max_parts_in_total)
{
ProfileEvents::increment(ProfileEvents::RejectedInserts);
throw Exception("Too many parts (" + toString(parts_count_in_total) + ") in all partitions in total. This indicates wrong choice of partition key. The threshold can be modified with 'max_parts_in_total' setting in <merge_tree> element in config.xml or with per-table setting.", ErrorCodes::TOO_MANY_PARTS);
}
size_t parts_count_in_partition = getMaxPartsCountForPartition();
ssize_t k_inactive = -1;
if (settings->inactive_parts_to_throw_insert > 0 || settings->inactive_parts_to_delay_insert > 0)
{
size_t inactive_parts_count_in_partition = getMaxInactivePartsCountForPartition();
if (inactive_parts_count_in_partition >= settings->inactive_parts_to_throw_insert)
{
ProfileEvents::increment(ProfileEvents::RejectedInserts);
throw Exception(
ErrorCodes::TOO_MANY_PARTS,
"Too many inactive parts ({}). Parts cleaning are processing significantly slower than inserts",
inactive_parts_count_in_partition);
}
k_inactive = ssize_t(inactive_parts_count_in_partition) - ssize_t(settings->inactive_parts_to_delay_insert);
}
if (parts_count_in_partition >= settings->parts_to_throw_insert)
{
ProfileEvents::increment(ProfileEvents::RejectedInserts);
throw Exception(
ErrorCodes::TOO_MANY_PARTS,
"Too many parts ({}). Parts cleaning are processing significantly slower than inserts",
parts_count_in_partition);
}
if (k_inactive < 0 && parts_count_in_partition < settings->parts_to_delay_insert)
return;
const ssize_t k_active = ssize_t(parts_count_in_partition) - ssize_t(settings->parts_to_delay_insert);
size_t max_k;
size_t k;
if (k_active > k_inactive)
{
max_k = settings->parts_to_throw_insert - settings->parts_to_delay_insert;
k = k_active + 1;
}
else
{
max_k = settings->inactive_parts_to_throw_insert - settings->inactive_parts_to_delay_insert;
k = k_inactive + 1;
}
const double delay_milliseconds = ::pow(settings->max_delay_to_insert * 1000, static_cast<double>(k) / max_k);
ProfileEvents::increment(ProfileEvents::DelayedInserts);
ProfileEvents::increment(ProfileEvents::DelayedInsertsMilliseconds, delay_milliseconds);
CurrentMetrics::Increment metric_increment(CurrentMetrics::DelayedInserts);
LOG_INFO(log, "Delaying inserting block by {} ms. because there are {} parts", delay_milliseconds, parts_count_in_partition);
if (until)
until->tryWait(delay_milliseconds);
else
std::this_thread::sleep_for(std::chrono::milliseconds(static_cast<size_t>(delay_milliseconds)));
}
MergeTreeData::DataPartPtr MergeTreeData::getActiveContainingPart(
const MergeTreePartInfo & part_info, MergeTreeData::DataPartState state, DataPartsLock & /*lock*/) const
{
auto current_state_parts_range = getDataPartsStateRange(state);
/// The part can be covered only by the previous or the next one in data_parts.
auto it = data_parts_by_state_and_info.lower_bound(DataPartStateAndInfo{state, part_info});
if (it != current_state_parts_range.end())
{
if ((*it)->info == part_info)
return *it;
if ((*it)->info.contains(part_info))
return *it;
}
if (it != current_state_parts_range.begin())
{
--it;
if ((*it)->info.contains(part_info))
return *it;
}
return nullptr;
}
void MergeTreeData::swapActivePart(MergeTreeData::DataPartPtr part_copy)
{
auto lock = lockParts();
for (auto original_active_part : getDataPartsStateRange(DataPartState::Committed)) // NOLINT (copy is intended)
{
if (part_copy->name == original_active_part->name)
{
auto active_part_it = data_parts_by_info.find(original_active_part->info);
if (active_part_it == data_parts_by_info.end())
throw Exception("Cannot swap part '" + part_copy->name + "', no such active part.", ErrorCodes::NO_SUCH_DATA_PART);
modifyPartState(original_active_part, DataPartState::DeleteOnDestroy);
data_parts_indexes.erase(active_part_it);
auto part_it = data_parts_indexes.insert(part_copy).first;
modifyPartState(part_it, DataPartState::Committed);
removePartContributionToDataVolume(original_active_part);
addPartContributionToDataVolume(part_copy);
auto disk = original_active_part->volume->getDisk();
String marker_path = original_active_part->getFullRelativePath() + IMergeTreeDataPart::DELETE_ON_DESTROY_MARKER_FILE_NAME;
try
{
disk->createFile(marker_path);
}
catch (Poco::Exception & e)
{
LOG_ERROR(log, "{} (while creating DeleteOnDestroy marker: {})", e.what(), backQuote(fullPath(disk, marker_path)));
}
return;
}
}
throw Exception("Cannot swap part '" + part_copy->name + "', no such active part.", ErrorCodes::NO_SUCH_DATA_PART);
}
MergeTreeData::DataPartPtr MergeTreeData::getActiveContainingPart(const MergeTreePartInfo & part_info) const
{
auto lock = lockParts();
return getActiveContainingPart(part_info, DataPartState::Committed, lock);
}
MergeTreeData::DataPartPtr MergeTreeData::getActiveContainingPart(const String & part_name) const
{
auto part_info = MergeTreePartInfo::fromPartName(part_name, format_version);
return getActiveContainingPart(part_info);
}
MergeTreeData::DataPartsVector MergeTreeData::getDataPartsVectorInPartition(MergeTreeData::DataPartState state, const String & partition_id)
{
DataPartStateAndPartitionID state_with_partition{state, partition_id};
auto lock = lockParts();
return DataPartsVector(
data_parts_by_state_and_info.lower_bound(state_with_partition),
data_parts_by_state_and_info.upper_bound(state_with_partition));
}
MergeTreeData::DataPartPtr MergeTreeData::getPartIfExists(const MergeTreePartInfo & part_info, const MergeTreeData::DataPartStates & valid_states)
{
auto lock = lockParts();
auto it = data_parts_by_info.find(part_info);
if (it == data_parts_by_info.end())
return nullptr;
for (auto state : valid_states)
if ((*it)->getState() == state)
return *it;
return nullptr;
}
MergeTreeData::DataPartPtr MergeTreeData::getPartIfExists(const String & part_name, const MergeTreeData::DataPartStates & valid_states)
{
return getPartIfExists(MergeTreePartInfo::fromPartName(part_name, format_version), valid_states);
}
static void loadPartAndFixMetadataImpl(MergeTreeData::MutableDataPartPtr part)
{
auto disk = part->volume->getDisk();
String full_part_path = part->getFullRelativePath();
part->loadColumnsChecksumsIndexes(false, true);
part->modification_time = disk->getLastModified(full_part_path).epochTime();
}
void MergeTreeData::calculateColumnSizesImpl()
{
column_sizes.clear();
/// Take into account only committed parts
auto committed_parts_range = getDataPartsStateRange(DataPartState::Committed);
for (const auto & part : committed_parts_range)
addPartContributionToColumnSizes(part);
}
void MergeTreeData::addPartContributionToColumnSizes(const DataPartPtr & part)
{
for (const auto & column : part->getColumns())
{
ColumnSize & total_column_size = column_sizes[column.name];
ColumnSize part_column_size = part->getColumnSize(column.name, *column.type);
total_column_size.add(part_column_size);
}
}
void MergeTreeData::removePartContributionToColumnSizes(const DataPartPtr & part)
{
for (const auto & column : part->getColumns())
{
ColumnSize & total_column_size = column_sizes[column.name];
ColumnSize part_column_size = part->getColumnSize(column.name, *column.type);
auto log_subtract = [&](size_t & from, size_t value, const char * field)
{
if (value > from)
LOG_ERROR(log, "Possibly incorrect column size subtraction: {} - {} = {}, column: {}, field: {}",
from, value, from - value, column.name, field);
from -= value;
};
log_subtract(total_column_size.data_compressed, part_column_size.data_compressed, ".data_compressed");
log_subtract(total_column_size.data_uncompressed, part_column_size.data_uncompressed, ".data_uncompressed");
log_subtract(total_column_size.marks, part_column_size.marks, ".marks");
}
}
PartitionCommandsResultInfo MergeTreeData::freezePartition(const ASTPtr & partition_ast, const StorageMetadataPtr & metadata_snapshot, const String & with_name, const Context & context, TableLockHolder &)
{
std::optional<String> prefix;
String partition_id;
if (format_version < MERGE_TREE_DATA_MIN_FORMAT_VERSION_WITH_CUSTOM_PARTITIONING)
{
/// Month-partitioning specific - partition value can represent a prefix of the partition to freeze.
if (const auto * partition_lit = partition_ast->as<ASTPartition &>().value->as<ASTLiteral>())
prefix = partition_lit->value.getType() == Field::Types::UInt64
? toString(partition_lit->value.get<UInt64>())
: partition_lit->value.safeGet<String>();
else
partition_id = getPartitionIDFromQuery(partition_ast, context);
}
else
partition_id = getPartitionIDFromQuery(partition_ast, context);
if (prefix)
LOG_DEBUG(log, "Freezing parts with prefix {}", *prefix);
else
LOG_DEBUG(log, "Freezing parts with partition ID {}", partition_id);
return freezePartitionsByMatcher(
[&prefix, &partition_id](const DataPartPtr & part)
{
if (prefix)
return startsWith(part->info.partition_id, *prefix);
else
return part->info.partition_id == partition_id;
},
metadata_snapshot,
with_name,
context);
}
void MergeTreeData::checkAlterPartitionIsPossible(const PartitionCommands & commands, const StorageMetadataPtr & /*metadata_snapshot*/, const Settings & settings) const
{
for (const auto & command : commands)
{
if (command.type == PartitionCommand::DROP_DETACHED_PARTITION
&& !settings.allow_drop_detached)
throw DB::Exception("Cannot execute query: DROP DETACHED PART is disabled "
"(see allow_drop_detached setting)", ErrorCodes::SUPPORT_IS_DISABLED);
if (command.partition && command.type != PartitionCommand::DROP_DETACHED_PARTITION)
{
if (command.part)
{
auto part_name = command.partition->as<ASTLiteral &>().value.safeGet<String>();
/// We able to parse it
MergeTreePartInfo::fromPartName(part_name, format_version);
}
else
{
/// We able to parse it
getPartitionIDFromQuery(command.partition, global_context);
}
}
}
}
void MergeTreeData::checkPartitionCanBeDropped(const ASTPtr & partition)
{
const String partition_id = getPartitionIDFromQuery(partition, global_context);
auto parts_to_remove = getDataPartsVectorInPartition(MergeTreeDataPartState::Committed, partition_id);
UInt64 partition_size = 0;
for (const auto & part : parts_to_remove)
partition_size += part->getBytesOnDisk();
auto table_id = getStorageID();
global_context.checkPartitionCanBeDropped(table_id.database_name, table_id.table_name, partition_size);
}
void MergeTreeData::checkPartCanBeDropped(const ASTPtr & part_ast)
{
String part_name = part_ast->as<ASTLiteral &>().value.safeGet<String>();
auto part = getPartIfExists(part_name, {MergeTreeDataPartState::Committed});
if (!part)
throw Exception(ErrorCodes::NO_SUCH_DATA_PART, "No part {} in committed state", part_name);
auto table_id = getStorageID();
global_context.checkPartitionCanBeDropped(table_id.database_name, table_id.table_name, part->getBytesOnDisk());
}
void MergeTreeData::movePartitionToDisk(const ASTPtr & partition, const String & name, bool moving_part, const Context & context)
{
String partition_id;
if (moving_part)
partition_id = partition->as<ASTLiteral &>().value.safeGet<String>();
else
partition_id = getPartitionIDFromQuery(partition, context);
DataPartsVector parts;
if (moving_part)
{
auto part_info = MergeTreePartInfo::fromPartName(partition_id, format_version);
parts.push_back(getActiveContainingPart(part_info));
if (!parts.back() || parts.back()->name != part_info.getPartName())
throw Exception("Part " + partition_id + " is not exists or not active", ErrorCodes::NO_SUCH_DATA_PART);
}
else
parts = getDataPartsVectorInPartition(MergeTreeDataPartState::Committed, partition_id);
auto disk = getStoragePolicy()->getDiskByName(name);
if (!disk)
throw Exception("Disk " + name + " does not exists on policy " + getStoragePolicy()->getName(), ErrorCodes::UNKNOWN_DISK);
parts.erase(std::remove_if(parts.begin(), parts.end(), [&](auto part_ptr)
{
return part_ptr->volume->getDisk()->getName() == disk->getName();
}), parts.end());
if (parts.empty())
{
String no_parts_to_move_message;
if (moving_part)
no_parts_to_move_message = "Part '" + partition_id + "' is already on disk '" + disk->getName() + "'";
else
no_parts_to_move_message = "All parts of partition '" + partition_id + "' are already on disk '" + disk->getName() + "'";
throw Exception(no_parts_to_move_message, ErrorCodes::UNKNOWN_DISK);
}
if (!movePartsToSpace(parts, std::static_pointer_cast<Space>(disk)))
throw Exception("Cannot move parts because moves are manually disabled", ErrorCodes::ABORTED);
}
void MergeTreeData::movePartitionToVolume(const ASTPtr & partition, const String & name, bool moving_part, const Context & context)
{
String partition_id;
if (moving_part)
partition_id = partition->as<ASTLiteral &>().value.safeGet<String>();
else
partition_id = getPartitionIDFromQuery(partition, context);
DataPartsVector parts;
if (moving_part)
{
auto part_info = MergeTreePartInfo::fromPartName(partition_id, format_version);
parts.emplace_back(getActiveContainingPart(part_info));
if (!parts.back() || parts.back()->name != part_info.getPartName())
throw Exception("Part " + partition_id + " is not exists or not active", ErrorCodes::NO_SUCH_DATA_PART);
}
else
parts = getDataPartsVectorInPartition(MergeTreeDataPartState::Committed, partition_id);
auto volume = getStoragePolicy()->getVolumeByName(name);
if (!volume)
throw Exception("Volume " + name + " does not exists on policy " + getStoragePolicy()->getName(), ErrorCodes::UNKNOWN_DISK);
if (parts.empty())
throw Exception("Nothing to move", ErrorCodes::NO_SUCH_DATA_PART);
parts.erase(std::remove_if(parts.begin(), parts.end(), [&](auto part_ptr)
{
for (const auto & disk : volume->getDisks())
{
if (part_ptr->volume->getDisk()->getName() == disk->getName())
{
return true;
}
}
return false;
}), parts.end());
if (parts.empty())
{
String no_parts_to_move_message;
if (moving_part)
no_parts_to_move_message = "Part '" + partition_id + "' is already on volume '" + volume->getName() + "'";
else
no_parts_to_move_message = "All parts of partition '" + partition_id + "' are already on volume '" + volume->getName() + "'";
throw Exception(no_parts_to_move_message, ErrorCodes::UNKNOWN_DISK);
}
if (!movePartsToSpace(parts, std::static_pointer_cast<Space>(volume)))
throw Exception("Cannot move parts because moves are manually disabled", ErrorCodes::ABORTED);
}
void MergeTreeData::fetchPartition(const ASTPtr & /*partition*/, const StorageMetadataPtr & /*metadata_snapshot*/, const String & /*from*/, const Context & /*query_context*/)
{
throw Exception(ErrorCodes::NOT_IMPLEMENTED, "FETCH PARTITION is not supported by storage {}", getName());
}
Pipe MergeTreeData::alterPartition(
const StorageMetadataPtr & metadata_snapshot,
const PartitionCommands & commands,
const Context & query_context)
{
PartitionCommandsResultInfo result;
for (const PartitionCommand & command : commands)
{
PartitionCommandsResultInfo current_command_results;
switch (command.type)
{
case PartitionCommand::DROP_PARTITION:
if (command.part)
checkPartCanBeDropped(command.partition);
else
checkPartitionCanBeDropped(command.partition);
dropPartition(command.partition, command.detach, command.part, query_context);
break;
case PartitionCommand::DROP_DETACHED_PARTITION:
dropDetached(command.partition, command.part, query_context);
break;
case PartitionCommand::ATTACH_PARTITION:
current_command_results = attachPartition(command.partition, metadata_snapshot, command.part, query_context);
break;
case PartitionCommand::MOVE_PARTITION:
{
switch (*command.move_destination_type)
{
case PartitionCommand::MoveDestinationType::DISK:
movePartitionToDisk(command.partition, command.move_destination_name, command.part, query_context);
break;
case PartitionCommand::MoveDestinationType::VOLUME:
movePartitionToVolume(command.partition, command.move_destination_name, command.part, query_context);
break;
case PartitionCommand::MoveDestinationType::TABLE:
checkPartitionCanBeDropped(command.partition);
String dest_database = query_context.resolveDatabase(command.to_database);
auto dest_storage = DatabaseCatalog::instance().getTable({dest_database, command.to_table}, query_context);
movePartitionToTable(dest_storage, command.partition, query_context);
break;
}
}
break;
case PartitionCommand::REPLACE_PARTITION:
{
checkPartitionCanBeDropped(command.partition);
String from_database = query_context.resolveDatabase(command.from_database);
auto from_storage = DatabaseCatalog::instance().getTable({from_database, command.from_table}, query_context);
replacePartitionFrom(from_storage, command.partition, command.replace, query_context);
}
break;
case PartitionCommand::FETCH_PARTITION:
fetchPartition(command.partition, metadata_snapshot, command.from_zookeeper_path, query_context);
break;
case PartitionCommand::FREEZE_PARTITION:
{
auto lock = lockForShare(query_context.getCurrentQueryId(), query_context.getSettingsRef().lock_acquire_timeout);
current_command_results = freezePartition(command.partition, metadata_snapshot, command.with_name, query_context, lock);
}
break;
case PartitionCommand::FREEZE_ALL_PARTITIONS:
{
auto lock = lockForShare(query_context.getCurrentQueryId(), query_context.getSettingsRef().lock_acquire_timeout);
current_command_results = freezeAll(command.with_name, metadata_snapshot, query_context, lock);
}
break;
}
for (auto & command_result : current_command_results)
command_result.command_type = command.typeToString();
result.insert(result.end(), current_command_results.begin(), current_command_results.end());
}
if (query_context.getSettingsRef().alter_partition_verbose_result)
return convertCommandsResultToSource(result);
return {};
}
String MergeTreeData::getPartitionIDFromQuery(const ASTPtr & ast, const Context & context) const
{
const auto & partition_ast = ast->as<ASTPartition &>();
if (!partition_ast.value)
return partition_ast.id;
if (format_version < MERGE_TREE_DATA_MIN_FORMAT_VERSION_WITH_CUSTOM_PARTITIONING)
{
/// Month-partitioning specific - partition ID can be passed in the partition value.
const auto * partition_lit = partition_ast.value->as<ASTLiteral>();
if (partition_lit && partition_lit->value.getType() == Field::Types::String)
{
String partition_id = partition_lit->value.get<String>();
if (partition_id.size() != 6 || !std::all_of(partition_id.begin(), partition_id.end(), isNumericASCII))
throw Exception(
"Invalid partition format: " + partition_id + ". Partition should consist of 6 digits: YYYYMM",
ErrorCodes::INVALID_PARTITION_VALUE);
return partition_id;
}
}
/// Re-parse partition key fields using the information about expected field types.
auto metadata_snapshot = getInMemoryMetadataPtr();
size_t fields_count = metadata_snapshot->getPartitionKey().sample_block.columns();
if (partition_ast.fields_count != fields_count)
throw Exception(
"Wrong number of fields in the partition expression: " + toString(partition_ast.fields_count) +
", must be: " + toString(fields_count),
ErrorCodes::INVALID_PARTITION_VALUE);
const FormatSettings format_settings;
Row partition_row(fields_count);
if (fields_count)
{
ReadBufferFromMemory left_paren_buf("(", 1);
ReadBufferFromMemory fields_buf(partition_ast.fields_str.data(), partition_ast.fields_str.size());
ReadBufferFromMemory right_paren_buf(")", 1);
ConcatReadBuffer buf({&left_paren_buf, &fields_buf, &right_paren_buf});
auto input_format = FormatFactory::instance().getInput("Values", buf, metadata_snapshot->getPartitionKey().sample_block, context, context.getSettingsRef().max_block_size);
auto input_stream = std::make_shared<InputStreamFromInputFormat>(input_format);
auto block = input_stream->read();
if (!block || !block.rows())
throw Exception(
"Could not parse partition value: `" + partition_ast.fields_str + "`",
ErrorCodes::INVALID_PARTITION_VALUE);
for (size_t i = 0; i < fields_count; ++i)
block.getByPosition(i).column->get(0, partition_row[i]);
}
MergeTreePartition partition(std::move(partition_row));
String partition_id = partition.getID(*this);
{
auto data_parts_lock = lockParts();
DataPartPtr existing_part_in_partition = getAnyPartInPartition(partition_id, data_parts_lock);
if (existing_part_in_partition && existing_part_in_partition->partition.value != partition.value)
{
WriteBufferFromOwnString buf;
writeCString("Parsed partition value: ", buf);
partition.serializeText(*this, buf, format_settings);
writeCString(" doesn't match partition value for an existing part with the same partition ID: ", buf);
writeString(existing_part_in_partition->name, buf);
throw Exception(buf.str(), ErrorCodes::INVALID_PARTITION_VALUE);
}
}
return partition_id;
}
MergeTreeData::DataPartsVector MergeTreeData::getDataPartsVector(const DataPartStates & affordable_states, DataPartStateVector * out_states) const
{
DataPartsVector res;
DataPartsVector buf;
{
auto lock = lockParts();
for (auto state : affordable_states)
{
std::swap(buf, res);
res.clear();
auto range = getDataPartsStateRange(state);
std::merge(range.begin(), range.end(), buf.begin(), buf.end(), std::back_inserter(res), LessDataPart());
}
if (out_states != nullptr)
{
out_states->resize(res.size());
for (size_t i = 0; i < res.size(); ++i)
(*out_states)[i] = res[i]->getState();
}
}
return res;
}
MergeTreeData::DataPartsVector MergeTreeData::getAllDataPartsVector(MergeTreeData::DataPartStateVector * out_states) const
{
DataPartsVector res;
{
auto lock = lockParts();
res.assign(data_parts_by_info.begin(), data_parts_by_info.end());
if (out_states != nullptr)
{
out_states->resize(res.size());
for (size_t i = 0; i < res.size(); ++i)
(*out_states)[i] = res[i]->getState();
}
}
return res;
}
std::vector<DetachedPartInfo>
MergeTreeData::getDetachedParts() const
{
std::vector<DetachedPartInfo> res;
for (const auto & [path, disk] : getRelativeDataPathsWithDisks())
{
for (auto it = disk->iterateDirectory(path + "detached"); it->isValid(); it->next())
{
res.emplace_back();
auto & part = res.back();
DetachedPartInfo::tryParseDetachedPartName(it->name(), part, format_version);
part.disk = disk->getName();
}
}
return res;
}
void MergeTreeData::validateDetachedPartName(const String & name) const
{
if (name.find('/') != std::string::npos || name == "." || name == "..")
throw DB::Exception("Invalid part name '" + name + "'", ErrorCodes::INCORRECT_FILE_NAME);
auto full_path = getFullRelativePathForPart(name, "detached/");
if (!full_path)
throw DB::Exception("Detached part \"" + name + "\" not found" , ErrorCodes::BAD_DATA_PART_NAME);
if (startsWith(name, "attaching_") || startsWith(name, "deleting_"))
throw DB::Exception("Cannot drop part " + name + ": "
"most likely it is used by another DROP or ATTACH query.",
ErrorCodes::BAD_DATA_PART_NAME);
}
void MergeTreeData::dropDetached(const ASTPtr & partition, bool part, const Context & context)
{
PartsTemporaryRename renamed_parts(*this, "detached/");
if (part)
{
String part_name = partition->as<ASTLiteral &>().value.safeGet<String>();
validateDetachedPartName(part_name);
renamed_parts.addPart(part_name, "deleting_" + part_name);
}
else
{
String partition_id = getPartitionIDFromQuery(partition, context);
DetachedPartsInfo detached_parts = getDetachedParts();
for (const auto & part_info : detached_parts)
if (part_info.valid_name && part_info.partition_id == partition_id
&& part_info.prefix != "attaching" && part_info.prefix != "deleting")
renamed_parts.addPart(part_info.dir_name, "deleting_" + part_info.dir_name);
}
LOG_DEBUG(log, "Will drop {} detached parts.", renamed_parts.old_and_new_names.size());
renamed_parts.tryRenameAll();
for (auto & [old_name, new_name] : renamed_parts.old_and_new_names)
{
const auto & [path, disk] = renamed_parts.old_part_name_to_path_and_disk[old_name];
disk->removeRecursive(path + "detached/" + new_name + "/");
LOG_DEBUG(log, "Dropped detached part {}", old_name);
old_name.clear();
}
}
MergeTreeData::MutableDataPartsVector MergeTreeData::tryLoadPartsToAttach(const ASTPtr & partition, bool attach_part,
const Context & context, PartsTemporaryRename & renamed_parts)
{
String source_dir = "detached/";
std::map<String, DiskPtr> name_to_disk;
/// Let's compose a list of parts that should be added.
if (attach_part)
{
String part_id = partition->as<ASTLiteral &>().value.safeGet<String>();
validateDetachedPartName(part_id);
renamed_parts.addPart(part_id, "attaching_" + part_id);
if (MergeTreePartInfo::tryParsePartName(part_id, nullptr, format_version))
name_to_disk[part_id] = getDiskForPart(part_id, source_dir);
}
else
{
String partition_id = getPartitionIDFromQuery(partition, context);
LOG_DEBUG(log, "Looking for parts for partition {} in {}", partition_id, source_dir);
ActiveDataPartSet active_parts(format_version);
const auto disks = getStoragePolicy()->getDisks();
for (const auto & disk : disks)
{
for (auto it = disk->iterateDirectory(relative_data_path + source_dir); it->isValid(); it->next())
{
const String & name = it->name();
MergeTreePartInfo part_info;
// TODO what if name contains "_tryN" suffix?
/// Parts with prefix in name (e.g. attaching_1_3_3_0, deleting_1_3_3_0) will be ignored
if (!MergeTreePartInfo::tryParsePartName(name, &part_info, format_version)
|| part_info.partition_id != partition_id)
{
continue;
}
LOG_DEBUG(log, "Found part {}", name);
active_parts.add(name);
name_to_disk[name] = disk;
}
}
LOG_DEBUG(log, "{} of them are active", active_parts.size());
/// Inactive parts rename so they can not be attached in case of repeated ATTACH.
for (const auto & [name, disk] : name_to_disk)
{
String containing_part = active_parts.getContainingPart(name);
if (!containing_part.empty() && containing_part != name)
{
// TODO maybe use PartsTemporaryRename here?
disk->moveDirectory(relative_data_path + source_dir + name, relative_data_path + source_dir + "inactive_" + name);
}
else
renamed_parts.addPart(name, "attaching_" + name);
}
}
/// Try to rename all parts before attaching to prevent race with DROP DETACHED and another ATTACH.
renamed_parts.tryRenameAll();
/// Synchronously check that added parts exist and are not broken. We will write checksums.txt if it does not exist.
LOG_DEBUG(log, "Checking parts");
MutableDataPartsVector loaded_parts;
loaded_parts.reserve(renamed_parts.old_and_new_names.size());
for (const auto & part_names : renamed_parts.old_and_new_names)
{
LOG_DEBUG(log, "Checking part {}", part_names.second);
auto single_disk_volume = std::make_shared<SingleDiskVolume>("volume_" + part_names.first, name_to_disk[part_names.first], 0);
MutableDataPartPtr part = createPart(part_names.first, single_disk_volume, source_dir + part_names.second);
loadPartAndFixMetadataImpl(part);
loaded_parts.push_back(part);
}
return loaded_parts;
}
namespace
{
inline ReservationPtr checkAndReturnReservation(UInt64 expected_size, ReservationPtr reservation)
{
if (reservation)
return reservation;
throw Exception(fmt::format("Cannot reserve {}, not enough space", ReadableSize(expected_size)), ErrorCodes::NOT_ENOUGH_SPACE);
}
}
ReservationPtr MergeTreeData::reserveSpace(UInt64 expected_size) const
{
expected_size = std::max(RESERVATION_MIN_ESTIMATION_SIZE, expected_size);
return getStoragePolicy()->reserveAndCheck(expected_size);
}
ReservationPtr MergeTreeData::reserveSpace(UInt64 expected_size, SpacePtr space)
{
expected_size = std::max(RESERVATION_MIN_ESTIMATION_SIZE, expected_size);
auto reservation = tryReserveSpace(expected_size, space);
return checkAndReturnReservation(expected_size, std::move(reservation));
}
ReservationPtr MergeTreeData::tryReserveSpace(UInt64 expected_size, SpacePtr space)
{
expected_size = std::max(RESERVATION_MIN_ESTIMATION_SIZE, expected_size);
return space->reserve(expected_size);
}
ReservationPtr MergeTreeData::reserveSpacePreferringTTLRules(
const StorageMetadataPtr & metadata_snapshot,
UInt64 expected_size,
const IMergeTreeDataPart::TTLInfos & ttl_infos,
time_t time_of_move,
size_t min_volume_index,
bool is_insert) const
{
expected_size = std::max(RESERVATION_MIN_ESTIMATION_SIZE, expected_size);
ReservationPtr reservation = tryReserveSpacePreferringTTLRules(metadata_snapshot, expected_size, ttl_infos, time_of_move, min_volume_index, is_insert);
return checkAndReturnReservation(expected_size, std::move(reservation));
}
ReservationPtr MergeTreeData::tryReserveSpacePreferringTTLRules(
const StorageMetadataPtr & metadata_snapshot,
UInt64 expected_size,
const IMergeTreeDataPart::TTLInfos & ttl_infos,
time_t time_of_move,
size_t min_volume_index,
bool is_insert) const
{
expected_size = std::max(RESERVATION_MIN_ESTIMATION_SIZE, expected_size);
ReservationPtr reservation;
auto move_ttl_entry = selectTTLDescriptionForTTLInfos(metadata_snapshot->getMoveTTLs(), ttl_infos.moves_ttl, time_of_move, true);
if (move_ttl_entry)
{
SpacePtr destination_ptr = getDestinationForMoveTTL(*move_ttl_entry, is_insert);
if (!destination_ptr)
{
if (move_ttl_entry->destination_type == DataDestinationType::VOLUME)
LOG_WARNING(log, "Would like to reserve space on volume '{}' by TTL rule of table '{}' but volume was not found or rule is not applicable at the moment",
move_ttl_entry->destination_name, log_name);
else if (move_ttl_entry->destination_type == DataDestinationType::DISK)
LOG_WARNING(log, "Would like to reserve space on disk '{}' by TTL rule of table '{}' but disk was not found or rule is not applicable at the moment",
move_ttl_entry->destination_name, log_name);
}
else
{
reservation = destination_ptr->reserve(expected_size);
if (reservation)
return reservation;
else
if (move_ttl_entry->destination_type == DataDestinationType::VOLUME)
LOG_WARNING(log, "Would like to reserve space on volume '{}' by TTL rule of table '{}' but there is not enough space",
move_ttl_entry->destination_name, log_name);
else if (move_ttl_entry->destination_type == DataDestinationType::DISK)
LOG_WARNING(log, "Would like to reserve space on disk '{}' by TTL rule of table '{}' but there is not enough space",
move_ttl_entry->destination_name, log_name);
}
}
reservation = getStoragePolicy()->reserve(expected_size, min_volume_index);
return reservation;
}
SpacePtr MergeTreeData::getDestinationForMoveTTL(const TTLDescription & move_ttl, bool is_insert) const
{
auto policy = getStoragePolicy();
if (move_ttl.destination_type == DataDestinationType::VOLUME)
{
auto volume = policy->getVolumeByName(move_ttl.destination_name);
if (!volume)
return {};
if (is_insert && !volume->perform_ttl_move_on_insert)
return {};
return volume;
}
else if (move_ttl.destination_type == DataDestinationType::DISK)
{
auto disk = policy->getDiskByName(move_ttl.destination_name);
if (!disk)
return {};
auto volume = policy->getVolume(policy->getVolumeIndexByDisk(disk));
if (!volume)
return {};
if (is_insert && !volume->perform_ttl_move_on_insert)
return {};
return disk;
}
else
return {};
}
bool MergeTreeData::isPartInTTLDestination(const TTLDescription & ttl, const IMergeTreeDataPart & part) const
{
auto policy = getStoragePolicy();
if (ttl.destination_type == DataDestinationType::VOLUME)
{
for (const auto & disk : policy->getVolumeByName(ttl.destination_name)->getDisks())
if (disk->getName() == part.volume->getDisk()->getName())
return true;
}
else if (ttl.destination_type == DataDestinationType::DISK)
return policy->getDiskByName(ttl.destination_name)->getName() == part.volume->getDisk()->getName();
return false;
}
CompressionCodecPtr MergeTreeData::getCompressionCodecForPart(size_t part_size_compressed, const IMergeTreeDataPart::TTLInfos & ttl_infos, time_t current_time) const
{
auto metadata_snapshot = getInMemoryMetadataPtr();
const auto & recompression_ttl_entries = metadata_snapshot->getRecompressionTTLs();
auto best_ttl_entry = selectTTLDescriptionForTTLInfos(recompression_ttl_entries, ttl_infos.recompression_ttl, current_time, true);
if (best_ttl_entry)
return CompressionCodecFactory::instance().get(best_ttl_entry->recompression_codec, {});
return global_context.chooseCompressionCodec(
part_size_compressed,
static_cast<double>(part_size_compressed) / getTotalActiveSizeInBytes());
}
MergeTreeData::DataParts MergeTreeData::getDataParts(const DataPartStates & affordable_states) const
{
DataParts res;
{
auto lock = lockParts();
for (auto state : affordable_states)
{
auto range = getDataPartsStateRange(state);
res.insert(range.begin(), range.end());
}
}
return res;
}
MergeTreeData::DataParts MergeTreeData::getDataParts() const
{
return getDataParts({DataPartState::Committed});
}
MergeTreeData::DataPartsVector MergeTreeData::getDataPartsVector() const
{
return getDataPartsVector({DataPartState::Committed});
}
MergeTreeData::DataPartPtr MergeTreeData::getAnyPartInPartition(
const String & partition_id, DataPartsLock & /*data_parts_lock*/) const
{
auto it = data_parts_by_state_and_info.lower_bound(DataPartStateAndPartitionID{DataPartState::Committed, partition_id});
if (it != data_parts_by_state_and_info.end() && (*it)->getState() == DataPartState::Committed && (*it)->info.partition_id == partition_id)
return *it;
return nullptr;
}
void MergeTreeData::Transaction::rollbackPartsToTemporaryState()
{
if (!isEmpty())
{
WriteBufferFromOwnString buf;
buf << " Rollbacking parts state to temporary and removing from working set:";
for (const auto & part : precommitted_parts)
buf << " " << part->relative_path;
buf << ".";
LOG_DEBUG(data.log, "Undoing transaction.{}", buf.str());
data.removePartsFromWorkingSetImmediatelyAndSetTemporaryState(
DataPartsVector(precommitted_parts.begin(), precommitted_parts.end()));
}
clear();
}
void MergeTreeData::Transaction::rollback()
{
if (!isEmpty())
{
WriteBufferFromOwnString buf;
buf << " Removing parts:";
for (const auto & part : precommitted_parts)
buf << " " << part->relative_path;
buf << ".";
LOG_DEBUG(data.log, "Undoing transaction.{}", buf.str());
data.removePartsFromWorkingSet(
DataPartsVector(precommitted_parts.begin(), precommitted_parts.end()),
/* clear_without_timeout = */ true);
}
clear();
}
MergeTreeData::DataPartsVector MergeTreeData::Transaction::commit(MergeTreeData::DataPartsLock * acquired_parts_lock)
{
DataPartsVector total_covered_parts;
if (!isEmpty())
{
auto parts_lock = acquired_parts_lock ? MergeTreeData::DataPartsLock() : data.lockParts();
auto * owing_parts_lock = acquired_parts_lock ? acquired_parts_lock : &parts_lock;
auto current_time = time(nullptr);
size_t add_bytes = 0;
size_t add_rows = 0;
size_t add_parts = 0;
size_t reduce_bytes = 0;
size_t reduce_rows = 0;
size_t reduce_parts = 0;
for (const DataPartPtr & part : precommitted_parts)
{
DataPartPtr covering_part;
DataPartsVector covered_parts = data.getActivePartsToReplace(part->info, part->name, covering_part, *owing_parts_lock);
if (covering_part)
{
LOG_WARNING(data.log, "Tried to commit obsolete part {} covered by {}", part->name, covering_part->getNameWithState());
part->remove_time.store(0, std::memory_order_relaxed); /// The part will be removed without waiting for old_parts_lifetime seconds.
data.modifyPartState(part, DataPartState::Outdated);
}
else
{
total_covered_parts.insert(total_covered_parts.end(), covered_parts.begin(), covered_parts.end());
for (const DataPartPtr & covered_part : covered_parts)
{
covered_part->remove_time.store(current_time, std::memory_order_relaxed);
reduce_bytes += covered_part->getBytesOnDisk();
reduce_rows += covered_part->rows_count;
data.modifyPartState(covered_part, DataPartState::Outdated);
data.removePartContributionToColumnSizes(covered_part);
}
reduce_parts += covered_parts.size();
add_bytes += part->getBytesOnDisk();
add_rows += part->rows_count;
++add_parts;
data.modifyPartState(part, DataPartState::Committed);
data.addPartContributionToColumnSizes(part);
}
}
data.decreaseDataVolume(reduce_bytes, reduce_rows, reduce_parts);
data.increaseDataVolume(add_bytes, add_rows, add_parts);
}
clear();
return total_covered_parts;
}
bool MergeTreeData::isPrimaryOrMinMaxKeyColumnPossiblyWrappedInFunctions(
const ASTPtr & node, const StorageMetadataPtr & metadata_snapshot) const
{
const String column_name = node->getColumnName();
for (const auto & name : metadata_snapshot->getPrimaryKeyColumns())
if (column_name == name)
return true;
for (const auto & name : getMinMaxColumnsNames(metadata_snapshot->getPartitionKey()))
if (column_name == name)
return true;
if (const auto * func = node->as<ASTFunction>())
if (func->arguments->children.size() == 1)
return isPrimaryOrMinMaxKeyColumnPossiblyWrappedInFunctions(func->arguments->children.front(), metadata_snapshot);
return false;
}
bool MergeTreeData::mayBenefitFromIndexForIn(
const ASTPtr & left_in_operand, const Context &, const StorageMetadataPtr & metadata_snapshot) const
{
/// Make sure that the left side of the IN operator contain part of the key.
/// If there is a tuple on the left side of the IN operator, at least one item of the tuple
/// must be part of the key (probably wrapped by a chain of some acceptable functions).
const auto * left_in_operand_tuple = left_in_operand->as<ASTFunction>();
const auto & index_wrapper_factory = MergeTreeIndexFactory::instance();
if (left_in_operand_tuple && left_in_operand_tuple->name == "tuple")
{
for (const auto & item : left_in_operand_tuple->arguments->children)
{
if (isPrimaryOrMinMaxKeyColumnPossiblyWrappedInFunctions(item, metadata_snapshot))
return true;
for (const auto & index : metadata_snapshot->getSecondaryIndices())
if (index_wrapper_factory.get(index)->mayBenefitFromIndexForIn(item))
return true;
}
/// The tuple itself may be part of the primary key, so check that as a last resort.
return isPrimaryOrMinMaxKeyColumnPossiblyWrappedInFunctions(left_in_operand, metadata_snapshot);
}
else
{
for (const auto & index : metadata_snapshot->getSecondaryIndices())
if (index_wrapper_factory.get(index)->mayBenefitFromIndexForIn(left_in_operand))
return true;
return isPrimaryOrMinMaxKeyColumnPossiblyWrappedInFunctions(left_in_operand, metadata_snapshot);
}
}
MergeTreeData & MergeTreeData::checkStructureAndGetMergeTreeData(IStorage & source_table, const StorageMetadataPtr & src_snapshot, const StorageMetadataPtr & my_snapshot) const
{
MergeTreeData * src_data = dynamic_cast<MergeTreeData *>(&source_table);
if (!src_data)
throw Exception("Table " + source_table.getStorageID().getNameForLogs() +
" supports attachPartitionFrom only for MergeTree family of table engines."
" Got " + source_table.getName(), ErrorCodes::NOT_IMPLEMENTED);
if (my_snapshot->getColumns().getAllPhysical().sizeOfDifference(src_snapshot->getColumns().getAllPhysical()))
throw Exception("Tables have different structure", ErrorCodes::INCOMPATIBLE_COLUMNS);
auto query_to_string = [] (const ASTPtr & ast)
{
return ast ? queryToString(ast) : "";
};
if (query_to_string(my_snapshot->getSortingKeyAST()) != query_to_string(src_snapshot->getSortingKeyAST()))
throw Exception("Tables have different ordering", ErrorCodes::BAD_ARGUMENTS);
if (query_to_string(my_snapshot->getPartitionKeyAST()) != query_to_string(src_snapshot->getPartitionKeyAST()))
throw Exception("Tables have different partition key", ErrorCodes::BAD_ARGUMENTS);
if (format_version != src_data->format_version)
throw Exception("Tables have different format_version", ErrorCodes::BAD_ARGUMENTS);
return *src_data;
}
MergeTreeData & MergeTreeData::checkStructureAndGetMergeTreeData(
const StoragePtr & source_table, const StorageMetadataPtr & src_snapshot, const StorageMetadataPtr & my_snapshot) const
{
return checkStructureAndGetMergeTreeData(*source_table, src_snapshot, my_snapshot);
}
MergeTreeData::MutableDataPartPtr MergeTreeData::cloneAndLoadDataPartOnSameDisk(
const MergeTreeData::DataPartPtr & src_part,
const String & tmp_part_prefix,
const MergeTreePartInfo & dst_part_info,
const StorageMetadataPtr & metadata_snapshot)
{
/// Check that the storage policy contains the disk where the src_part is located.
bool does_storage_policy_allow_same_disk = false;
for (const DiskPtr & disk : getStoragePolicy()->getDisks())
{
if (disk->getName() == src_part->volume->getDisk()->getName())
{
does_storage_policy_allow_same_disk = true;
break;
}
}
if (!does_storage_policy_allow_same_disk)
throw Exception(
"Could not clone and load part " + quoteString(src_part->getFullPath()) + " because disk does not belong to storage policy",
ErrorCodes::BAD_ARGUMENTS);
String dst_part_name = src_part->getNewName(dst_part_info);
String tmp_dst_part_name = tmp_part_prefix + dst_part_name;
auto reservation = reserveSpace(src_part->getBytesOnDisk(), src_part->volume->getDisk());
auto disk = reservation->getDisk();
String src_part_path = src_part->getFullRelativePath();
String dst_part_path = relative_data_path + tmp_dst_part_name;
if (disk->exists(dst_part_path))
throw Exception("Part in " + fullPath(disk, dst_part_path) + " already exists", ErrorCodes::DIRECTORY_ALREADY_EXISTS);
/// If source part is in memory, flush it to disk and clone it already in on-disk format
if (auto src_part_in_memory = asInMemoryPart(src_part))
{
const auto & src_relative_data_path = src_part_in_memory->storage.relative_data_path;
auto flushed_part_path = src_part_in_memory->getRelativePathForPrefix(tmp_part_prefix);
src_part_in_memory->flushToDisk(src_relative_data_path, flushed_part_path, metadata_snapshot);
src_part_path = src_relative_data_path + flushed_part_path + "/";
}
LOG_DEBUG(log, "Cloning part {} to {}", fullPath(disk, src_part_path), fullPath(disk, dst_part_path));
localBackup(disk, src_part_path, dst_part_path);
disk->removeFileIfExists(dst_part_path + "/" + IMergeTreeDataPart::DELETE_ON_DESTROY_MARKER_FILE_NAME);
auto single_disk_volume = std::make_shared<SingleDiskVolume>(disk->getName(), disk, 0);
auto dst_data_part = createPart(dst_part_name, dst_part_info, single_disk_volume, tmp_dst_part_name);
dst_data_part->is_temp = true;
dst_data_part->loadColumnsChecksumsIndexes(require_part_metadata, true);
dst_data_part->modification_time = disk->getLastModified(dst_part_path).epochTime();
return dst_data_part;
}
String MergeTreeData::getFullPathOnDisk(const DiskPtr & disk) const
{
return disk->getPath() + relative_data_path;
}
DiskPtr MergeTreeData::getDiskForPart(const String & part_name, const String & additional_path) const
{
const auto disks = getStoragePolicy()->getDisks();
for (const DiskPtr & disk : disks)
for (auto it = disk->iterateDirectory(relative_data_path + additional_path); it->isValid(); it->next())
if (it->name() == part_name)
return disk;
return nullptr;
}
std::optional<String> MergeTreeData::getFullRelativePathForPart(const String & part_name, const String & additional_path) const
{
auto disk = getDiskForPart(part_name, additional_path);
if (disk)
return relative_data_path + additional_path;
return {};
}
Strings MergeTreeData::getDataPaths() const
{
Strings res;
auto disks = getStoragePolicy()->getDisks();
for (const auto & disk : disks)
res.push_back(getFullPathOnDisk(disk));
return res;
}
MergeTreeData::PathsWithDisks MergeTreeData::getRelativeDataPathsWithDisks() const
{
PathsWithDisks res;
auto disks = getStoragePolicy()->getDisks();
for (const auto & disk : disks)
res.emplace_back(relative_data_path, disk);
return res;
}
PartitionCommandsResultInfo MergeTreeData::freezePartitionsByMatcher(MatcherFn matcher, const StorageMetadataPtr & metadata_snapshot, const String & with_name, const Context & context)
{
String clickhouse_path = Poco::Path(context.getPath()).makeAbsolute().toString();
String default_shadow_path = clickhouse_path + "shadow/";
Poco::File(default_shadow_path).createDirectories();
auto increment = Increment(default_shadow_path + "increment.txt").get(true);
const String shadow_path = "shadow/";
/// Acquire a snapshot of active data parts to prevent removing while doing backup.
const auto data_parts = getDataParts();
String backup_name = (!with_name.empty() ? escapeForFileName(with_name) : toString(increment));
String backup_path = shadow_path + backup_name + "/";
for (const auto & disk : getStoragePolicy()->getDisks())
disk->onFreeze(backup_path);
PartitionCommandsResultInfo result;
size_t parts_processed = 0;
for (const auto & part : data_parts)
{
if (!matcher(part))
continue;
LOG_DEBUG(log, "Freezing part {} snapshot will be placed at {}", part->name, backup_path);
part->volume->getDisk()->createDirectories(backup_path);
String backup_part_path = backup_path + relative_data_path + part->relative_path;
if (auto part_in_memory = asInMemoryPart(part))
part_in_memory->flushToDisk(backup_path + relative_data_path, part->relative_path, metadata_snapshot);
else
localBackup(part->volume->getDisk(), part->getFullRelativePath(), backup_part_path);
part->volume->getDisk()->removeFileIfExists(backup_part_path + "/" + IMergeTreeDataPart::DELETE_ON_DESTROY_MARKER_FILE_NAME);
part->is_frozen.store(true, std::memory_order_relaxed);
result.push_back(PartitionCommandResultInfo{
.partition_id = part->info.partition_id,
.part_name = part->name,
.backup_path = part->volume->getDisk()->getPath() + backup_path,
.part_backup_path = part->volume->getDisk()->getPath() + backup_part_path,
.backup_name = backup_name,
});
++parts_processed;
}
LOG_DEBUG(log, "Freezed {} parts", parts_processed);
return result;
}
bool MergeTreeData::canReplacePartition(const DataPartPtr & src_part) const
{
const auto settings = getSettings();
if (!settings->enable_mixed_granularity_parts || settings->index_granularity_bytes == 0)
{
if (!canUseAdaptiveGranularity() && src_part->index_granularity_info.is_adaptive)
return false;
if (canUseAdaptiveGranularity() && !src_part->index_granularity_info.is_adaptive)
return false;
}
return true;
}
inline UInt64 time_in_microseconds(std::chrono::time_point<std::chrono::system_clock> timepoint)
{
return std::chrono::duration_cast<std::chrono::microseconds>(timepoint.time_since_epoch()).count();
}
inline UInt64 time_in_seconds(std::chrono::time_point<std::chrono::system_clock> timepoint)
{
return std::chrono::duration_cast<std::chrono::seconds>(timepoint.time_since_epoch()).count();
}
void MergeTreeData::writePartLog(
PartLogElement::Type type,
const ExecutionStatus & execution_status,
UInt64 elapsed_ns,
const String & new_part_name,
const DataPartPtr & result_part,
const DataPartsVector & source_parts,
const MergeListEntry * merge_entry)
try
{
auto table_id = getStorageID();
auto part_log = global_context.getPartLog(table_id.database_name);
if (!part_log)
return;
PartLogElement part_log_elem;
part_log_elem.event_type = type;
part_log_elem.error = static_cast<UInt16>(execution_status.code);
part_log_elem.exception = execution_status.message;
// construct event_time and event_time_microseconds using the same time point
// so that the two times will always be equal up to a precision of a second.
const auto time_now = std::chrono::system_clock::now();
part_log_elem.event_time = time_in_seconds(time_now);
part_log_elem.event_time_microseconds = time_in_microseconds(time_now);
/// TODO: Stop stopwatch in outer code to exclude ZK timings and so on
part_log_elem.duration_ms = elapsed_ns / 1000000;
part_log_elem.database_name = table_id.database_name;
part_log_elem.table_name = table_id.table_name;
part_log_elem.partition_id = MergeTreePartInfo::fromPartName(new_part_name, format_version).partition_id;
part_log_elem.part_name = new_part_name;
if (result_part)
{
part_log_elem.path_on_disk = result_part->getFullPath();
part_log_elem.bytes_compressed_on_disk = result_part->getBytesOnDisk();
part_log_elem.rows = result_part->rows_count;
}
part_log_elem.source_part_names.reserve(source_parts.size());
for (const auto & source_part : source_parts)
part_log_elem.source_part_names.push_back(source_part->name);
if (merge_entry)
{
part_log_elem.rows_read = (*merge_entry)->rows_read;
part_log_elem.bytes_read_uncompressed = (*merge_entry)->bytes_read_uncompressed;
part_log_elem.rows = (*merge_entry)->rows_written;
part_log_elem.bytes_uncompressed = (*merge_entry)->bytes_written_uncompressed;
part_log_elem.peak_memory_usage = (*merge_entry)->memory_tracker.getPeak();
}
part_log->add(part_log_elem);
}
catch (...)
{
tryLogCurrentException(log, __PRETTY_FUNCTION__);
}
MergeTreeData::CurrentlyMovingPartsTagger::CurrentlyMovingPartsTagger(MergeTreeMovingParts && moving_parts_, MergeTreeData & data_)
: parts_to_move(std::move(moving_parts_)), data(data_)
{
for (const auto & moving_part : parts_to_move)
if (!data.currently_moving_parts.emplace(moving_part.part).second)
throw Exception("Cannot move part '" + moving_part.part->name + "'. It's already moving.", ErrorCodes::LOGICAL_ERROR);
}
MergeTreeData::CurrentlyMovingPartsTagger::~CurrentlyMovingPartsTagger()
{
std::lock_guard lock(data.moving_parts_mutex);
for (const auto & moving_part : parts_to_move)
{
/// Something went completely wrong
if (!data.currently_moving_parts.count(moving_part.part))
std::terminate();
data.currently_moving_parts.erase(moving_part.part);
}
}
std::optional<JobAndPool> MergeTreeData::getDataMovingJob()
{
if (parts_mover.moves_blocker.isCancelled())
return {};
auto moving_tagger = selectPartsForMove();
if (moving_tagger->parts_to_move.empty())
return {};
return JobAndPool{[this, moving_tagger] () mutable
{
return moveParts(moving_tagger);
}, PoolType::MOVE};
}
bool MergeTreeData::areBackgroundMovesNeeded() const
{
auto policy = getStoragePolicy();
if (policy->getVolumes().size() > 1)
return true;
return policy->getVolumes().size() == 1 && policy->getVolumes()[0]->getDisks().size() > 1;
}
bool MergeTreeData::movePartsToSpace(const DataPartsVector & parts, SpacePtr space)
{
if (parts_mover.moves_blocker.isCancelled())
return false;
auto moving_tagger = checkPartsForMove(parts, space);
if (moving_tagger->parts_to_move.empty())
return false;
return moveParts(moving_tagger);
}
MergeTreeData::CurrentlyMovingPartsTaggerPtr MergeTreeData::selectPartsForMove()
{
MergeTreeMovingParts parts_to_move;
auto can_move = [this](const DataPartPtr & part, String * reason) -> bool
{
if (partIsAssignedToBackgroundOperation(part))
{
*reason = "part already assigned to background operation.";
return false;
}
if (currently_moving_parts.count(part))
{
*reason = "part is already moving.";
return false;
}
return true;
};
std::lock_guard moving_lock(moving_parts_mutex);
parts_mover.selectPartsForMove(parts_to_move, can_move, moving_lock);
return std::make_shared<CurrentlyMovingPartsTagger>(std::move(parts_to_move), *this);
}
MergeTreeData::CurrentlyMovingPartsTaggerPtr MergeTreeData::checkPartsForMove(const DataPartsVector & parts, SpacePtr space)
{
std::lock_guard moving_lock(moving_parts_mutex);
MergeTreeMovingParts parts_to_move;
for (const auto & part : parts)
{
auto reservation = space->reserve(part->getBytesOnDisk());
if (!reservation)
throw Exception("Move is not possible. Not enough space on '" + space->getName() + "'", ErrorCodes::NOT_ENOUGH_SPACE);
auto reserved_disk = reservation->getDisk();
if (reserved_disk->exists(relative_data_path + part->name))
throw Exception(
"Move is not possible: " + fullPath(reserved_disk, relative_data_path + part->name) + " already exists",
ErrorCodes::DIRECTORY_ALREADY_EXISTS);
if (currently_moving_parts.count(part) || partIsAssignedToBackgroundOperation(part))
throw Exception(
"Cannot move part '" + part->name + "' because it's participating in background process",
ErrorCodes::PART_IS_TEMPORARILY_LOCKED);
parts_to_move.emplace_back(part, std::move(reservation));
}
return std::make_shared<CurrentlyMovingPartsTagger>(std::move(parts_to_move), *this);
}
bool MergeTreeData::moveParts(const CurrentlyMovingPartsTaggerPtr & moving_tagger)
{
LOG_INFO(log, "Got {} parts to move.", moving_tagger->parts_to_move.size());
for (const auto & moving_part : moving_tagger->parts_to_move)
{
Stopwatch stopwatch;
DataPartPtr cloned_part;
auto write_part_log = [&](const ExecutionStatus & execution_status)
{
writePartLog(
PartLogElement::Type::MOVE_PART,
execution_status,
stopwatch.elapsed(),
moving_part.part->name,
cloned_part,
{moving_part.part},
nullptr);
};
try
{
cloned_part = parts_mover.clonePart(moving_part);
parts_mover.swapClonedPart(cloned_part);
write_part_log({});
}
catch (...)
{
write_part_log(ExecutionStatus::fromCurrentException());
if (cloned_part)
cloned_part->remove();
throw;
}
}
return true;
}
bool MergeTreeData::canUsePolymorphicParts(const MergeTreeSettings & settings, String * out_reason) const
{
if (!canUseAdaptiveGranularity())
{
if (out_reason && (settings.min_rows_for_wide_part != 0 || settings.min_bytes_for_wide_part != 0
|| settings.min_rows_for_compact_part != 0 || settings.min_bytes_for_compact_part != 0))
{
*out_reason = fmt::format(
"Table can't create parts with adaptive granularity, but settings"
" min_rows_for_wide_part = {}"
", min_bytes_for_wide_part = {}"
", min_rows_for_compact_part = {}"
", min_bytes_for_compact_part = {}"
". Parts with non-adaptive granularity can be stored only in Wide (default) format.",
settings.min_rows_for_wide_part, settings.min_bytes_for_wide_part,
settings.min_rows_for_compact_part, settings.min_bytes_for_compact_part);
}
return false;
}
return true;
}
MergeTreeData::AlterConversions MergeTreeData::getAlterConversionsForPart(const MergeTreeDataPartPtr part) const
{
MutationCommands commands = getFirstAlterMutationCommandsForPart(part);
AlterConversions result{};
for (const auto & command : commands)
/// Currently we need explicit conversions only for RENAME alter
/// all other conversions can be deduced from diff between part columns
/// and columns in storage.
if (command.type == MutationCommand::Type::RENAME_COLUMN)
result.rename_map[command.rename_to] = command.column_name;
return result;
}
MergeTreeData::WriteAheadLogPtr MergeTreeData::getWriteAheadLog()
{
std::lock_guard lock(write_ahead_log_mutex);
if (!write_ahead_log)
{
auto reservation = reserveSpace(getSettings()->write_ahead_log_max_bytes);
write_ahead_log = std::make_shared<MergeTreeWriteAheadLog>(*this, reservation->getDisk());
}
return write_ahead_log;
}
NamesAndTypesList MergeTreeData::getVirtuals() const
{
return NamesAndTypesList{
NameAndTypePair("_part", std::make_shared<DataTypeString>()),
NameAndTypePair("_part_index", std::make_shared<DataTypeUInt64>()),
NameAndTypePair("_part_uuid", std::make_shared<DataTypeUUID>()),
NameAndTypePair("_partition_id", std::make_shared<DataTypeString>()),
NameAndTypePair("_sample_factor", std::make_shared<DataTypeFloat64>()),
};
}
size_t MergeTreeData::getTotalMergesWithTTLInMergeList() const
{
return global_context.getMergeList().getMergesWithTTLCount();
}
void MergeTreeData::addPartContributionToDataVolume(const DataPartPtr & part)
{
increaseDataVolume(part->getBytesOnDisk(), part->rows_count, 1);
}
void MergeTreeData::removePartContributionToDataVolume(const DataPartPtr & part)
{
decreaseDataVolume(part->getBytesOnDisk(), part->rows_count, 1);
}
void MergeTreeData::increaseDataVolume(size_t bytes, size_t rows, size_t parts)
{
total_active_size_bytes.fetch_add(bytes, std::memory_order_acq_rel);
total_active_size_rows.fetch_add(rows, std::memory_order_acq_rel);
total_active_size_parts.fetch_add(parts, std::memory_order_acq_rel);
}
void MergeTreeData::decreaseDataVolume(size_t bytes, size_t rows, size_t parts)
{
total_active_size_bytes.fetch_sub(bytes, std::memory_order_acq_rel);
total_active_size_rows.fetch_sub(rows, std::memory_order_acq_rel);
total_active_size_parts.fetch_sub(parts, std::memory_order_acq_rel);
}
void MergeTreeData::setDataVolume(size_t bytes, size_t rows, size_t parts)
{
total_active_size_bytes.store(bytes, std::memory_order_release);
total_active_size_rows.store(rows, std::memory_order_release);
total_active_size_parts.store(parts, std::memory_order_release);
}
void MergeTreeData::insertQueryIdOrThrow(const String & query_id, size_t max_queries) const
{
std::lock_guard lock(query_id_set_mutex);
if (query_id_set.find(query_id) != query_id_set.end())
return;
if (query_id_set.size() >= max_queries)
throw Exception(
ErrorCodes::TOO_MANY_SIMULTANEOUS_QUERIES, "Too many simultaneous queries for table {}. Maximum is: {}", log_name, max_queries);
query_id_set.insert(query_id);
}
void MergeTreeData::removeQueryId(const String & query_id) const
{
std::lock_guard lock(query_id_set_mutex);
if (query_id_set.find(query_id) == query_id_set.end())
LOG_WARNING(log, "We have query_id removed but it's not recorded. This is a bug");
else
query_id_set.erase(query_id);
}
}
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