ClickHouse/src/Dictionaries/CacheDictionaryStorage.h

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#pragma once
#include <chrono>
#include <variant>
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#include <pcg_random.hpp>
#include <Common/randomSeed.h>
#include <Common/Arena.h>
#include <Common/ArenaWithFreeLists.h>
#include <Common/HashTable/LRUHashMap.h>
#include <Dictionaries/DictionaryStructure.h>
#include <Dictionaries/ICacheDictionaryStorage.h>
#include <Dictionaries/DictionaryHelpers.h>
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namespace DB
{
namespace ErrorCodes
{
extern const int NOT_IMPLEMENTED;
}
struct CacheDictionaryStorageConfiguration
{
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/// Max size of storage in cells
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const size_t max_size_in_cells;
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/// Needed to perform check if cell is expired or not found. Default value is dictionary max lifetime.
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const size_t strict_max_lifetime_seconds;
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/// Lifetime of dictionary. Cell deadline is random value between lifetime min and max seconds.
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const DictionaryLifetime lifetime;
};
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/** ICacheDictionaryStorage implementation that keeps key in hash table with fixed collision length.
* Value in hash table point to index in attributes arrays.
*/
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template <DictionaryKeyType dictionary_key_type>
class CacheDictionaryStorage final : public ICacheDictionaryStorage
{
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static constexpr size_t max_collision_length = 10;
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public:
using KeyType = std::conditional_t<dictionary_key_type == DictionaryKeyType::simple, UInt64, StringRef>;
static_assert(dictionary_key_type != DictionaryKeyType::range, "Range key type is not supported by CacheDictionaryStorage");
explicit CacheDictionaryStorage(
const DictionaryStructure & dictionary_structure,
CacheDictionaryStorageConfiguration & configuration_)
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: configuration(configuration_)
, rnd_engine(randomSeed())
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{
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size_t cells_size = roundUpToPowerOfTwoOrZero(std::max(configuration.max_size_in_cells, max_collision_length));
cells.resize_fill(cells_size);
size_overlap_mask = cells_size - 1;
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setup(dictionary_structure);
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}
bool returnsFetchedColumnsInOrderOfRequestedKeys() const override { return true; }
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String getName() const override
{
if (dictionary_key_type == DictionaryKeyType::simple)
return "Cache";
else
return "ComplexKeyCache";
}
bool supportsSimpleKeys() const override { return dictionary_key_type == DictionaryKeyType::simple; }
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SimpleKeysStorageFetchResult fetchColumnsForKeys(
const PaddedPODArray<UInt64> & keys,
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const DictionaryStorageFetchRequest & fetch_request) override
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{
if constexpr (dictionary_key_type == DictionaryKeyType::simple)
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return fetchColumnsForKeysImpl<SimpleKeysStorageFetchResult>(keys, fetch_request);
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else
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throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Method fetchColumnsForKeys is not supported for complex key storage");
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}
void insertColumnsForKeys(const PaddedPODArray<UInt64> & keys, Columns columns) override
{
if constexpr (dictionary_key_type == DictionaryKeyType::simple)
insertColumnsForKeysImpl(keys, columns);
else
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throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Method insertColumnsForKeys is not supported for complex key storage");
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}
void insertDefaultKeys(const PaddedPODArray<UInt64> & keys) override
{
if constexpr (dictionary_key_type == DictionaryKeyType::simple)
insertDefaultKeysImpl(keys);
else
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throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Method insertDefaultKeysImpl is not supported for complex key storage");
}
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PaddedPODArray<UInt64> getCachedSimpleKeys() const override
{
if constexpr (dictionary_key_type == DictionaryKeyType::simple)
return getCachedKeysImpl();
else
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throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Method getCachedSimpleKeys is not supported for complex key storage");
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}
bool supportsComplexKeys() const override { return dictionary_key_type == DictionaryKeyType::complex; }
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ComplexKeysStorageFetchResult fetchColumnsForKeys(
const PaddedPODArray<StringRef> & keys,
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const DictionaryStorageFetchRequest & column_fetch_requests) override
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{
if constexpr (dictionary_key_type == DictionaryKeyType::complex)
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return fetchColumnsForKeysImpl<ComplexKeysStorageFetchResult>(keys, column_fetch_requests);
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else
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throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Method fetchColumnsForKeys is not supported for simple key storage");
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}
void insertColumnsForKeys(const PaddedPODArray<StringRef> & keys, Columns columns) override
{
if constexpr (dictionary_key_type == DictionaryKeyType::complex)
insertColumnsForKeysImpl(keys, columns);
else
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throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Method insertColumnsForKeys is not supported for simple key storage");
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}
void insertDefaultKeys(const PaddedPODArray<StringRef> & keys) override
{
if constexpr (dictionary_key_type == DictionaryKeyType::complex)
insertDefaultKeysImpl(keys);
else
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throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Method insertDefaultKeysImpl is not supported for simple key storage");
}
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PaddedPODArray<StringRef> getCachedComplexKeys() const override
{
if constexpr (dictionary_key_type == DictionaryKeyType::complex)
return getCachedKeysImpl();
else
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throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Method getCachedComplexKeys is not supported for simple key storage");
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}
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size_t getSize() const override { return size; }
double getLoadFactor() const override { return static_cast<double>(size) / configuration.max_size_in_cells; }
size_t getBytesAllocated() const override
{
size_t attributes_size_in_bytes = 0;
size_t attributes_size = attributes.size();
for (size_t attribute_index = 0; attribute_index < attributes_size; ++attribute_index)
{
getAttributeContainer(attribute_index, [&](const auto & container)
{
attributes_size_in_bytes += container.capacity() * sizeof(container[0]);
});
}
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return arena.size() + sizeof(Cell) * configuration.max_size_in_cells + attributes_size_in_bytes;
}
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private:
struct FetchedKey
{
FetchedKey(size_t element_index_, bool is_default_)
: element_index(element_index_)
, is_default(is_default_)
{}
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size_t element_index;
bool is_default;
};
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template <typename KeysStorageFetchResult>
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KeysStorageFetchResult fetchColumnsForKeysImpl(
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const PaddedPODArray<KeyType> & keys,
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const DictionaryStorageFetchRequest & fetch_request)
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{
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KeysStorageFetchResult result;
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result.fetched_columns = fetch_request.makeAttributesResultColumns();
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result.key_index_to_state.resize_fill(keys.size());
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const time_t now = std::chrono::system_clock::to_time_t(std::chrono::system_clock::now());
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size_t fetched_columns_index = 0;
size_t keys_size = keys.size();
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PaddedPODArray<FetchedKey> fetched_keys;
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fetched_keys.resize_fill(keys_size);
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for (size_t key_index = 0; key_index < keys_size; ++key_index)
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{
auto key = keys[key_index];
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auto [key_state, cell_index] = getKeyStateAndCellIndex(key, now);
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if (unlikely(key_state == KeyState::not_found))
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{
result.key_index_to_state[key_index] = {KeyState::not_found};
++result.not_found_keys_size;
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continue;
}
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auto & cell = cells[cell_index];
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result.expired_keys_size += static_cast<size_t>(key_state == KeyState::expired);
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result.key_index_to_state[key_index] = {key_state, fetched_columns_index};
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fetched_keys[fetched_columns_index] = FetchedKey(cell.element_index, cell.is_default);
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++fetched_columns_index;
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result.key_index_to_state[key_index].setDefaultValue(cell.is_default);
result.default_keys_size += cell.is_default;
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}
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result.found_keys_size = keys_size - (result.expired_keys_size + result.not_found_keys_size);
for (size_t attribute_index = 0; attribute_index < fetch_request.attributesSize(); ++attribute_index)
{
if (!fetch_request.shouldFillResultColumnWithIndex(attribute_index))
continue;
auto & attribute = attributes[attribute_index];
const auto & default_value_provider = fetch_request.defaultValueProviderAtIndex(attribute_index);
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size_t fetched_keys_size = fetched_keys.size();
auto & fetched_column = *result.fetched_columns[attribute_index];
fetched_column.reserve(fetched_keys_size);
if (unlikely(attribute.is_complex_type))
{
auto & container = std::get<std::vector<Field>>(attribute.attribute_container);
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for (size_t fetched_key_index = 0; fetched_key_index < fetched_columns_index; ++fetched_key_index)
{
auto fetched_key = fetched_keys[fetched_key_index];
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if (unlikely(fetched_key.is_default))
fetched_column.insert(default_value_provider.getDefaultValue(fetched_key_index));
else
fetched_column.insert(container[fetched_key.element_index]);
}
}
else
{
auto type_call = [&](const auto & dictionary_attribute_type)
{
using Type = std::decay_t<decltype(dictionary_attribute_type)>;
using AttributeType = typename Type::AttributeType;
using ValueType = DictionaryValueType<AttributeType>;
using ColumnType =
std::conditional_t<std::is_same_v<AttributeType, String>, ColumnString,
std::conditional_t<IsDecimalNumber<AttributeType>, ColumnDecimal<ValueType>,
ColumnVector<AttributeType>>>;
auto & container = std::get<PaddedPODArray<ValueType>>(attribute.attribute_container);
ColumnType & column_typed = static_cast<ColumnType &>(fetched_column);
if constexpr (std::is_same_v<ColumnType, ColumnString>)
{
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for (size_t fetched_key_index = 0; fetched_key_index < fetched_columns_index; ++fetched_key_index)
{
auto fetched_key = fetched_keys[fetched_key_index];
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if (unlikely(fetched_key.is_default))
column_typed.insert(default_value_provider.getDefaultValue(fetched_key_index));
else
{
auto item = container[fetched_key.element_index];
column_typed.insertData(item.data, item.size);
}
}
}
else
{
auto & data = column_typed.getData();
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for (size_t fetched_key_index = 0; fetched_key_index < fetched_columns_index; ++fetched_key_index)
{
auto fetched_key = fetched_keys[fetched_key_index];
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if (unlikely(fetched_key.is_default))
column_typed.insert(default_value_provider.getDefaultValue(fetched_key_index));
else
{
auto item = container[fetched_key.element_index];
data.push_back(item);
}
}
}
};
callOnDictionaryAttributeType(attribute.type, type_call);
}
}
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return result;
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}
void insertColumnsForKeysImpl(const PaddedPODArray<KeyType> & keys, Columns columns)
{
const auto now = std::chrono::system_clock::now();
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Field column_value;
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for (size_t key_index = 0; key_index < keys.size(); ++key_index)
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{
auto key = keys[key_index];
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size_t cell_index = getCellIndexForInsert(key);
auto & cell = cells[cell_index];
bool cell_was_default = cell.is_default;
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cell.is_default = false;
bool was_inserted = cell.deadline == 0;
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if (was_inserted)
{
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if constexpr (std::is_same_v<KeyType, StringRef>)
cell.key = copyStringInArena(key);
else
cell.key = key;
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for (size_t attribute_index = 0; attribute_index < columns.size(); ++attribute_index)
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{
auto & column = columns[attribute_index];
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getAttributeContainer(attribute_index, [&](auto & container)
{
container.emplace_back();
cell.element_index = container.size() - 1;
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using ElementType = std::decay_t<decltype(container[0])>;
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column->get(key_index, column_value);
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if constexpr (std::is_same_v<ElementType, Field>)
container.back() = column_value;
else if constexpr (std::is_same_v<ElementType, StringRef>)
{
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const String & string_value = column_value.get<String>();
StringRef string_value_ref = StringRef {string_value.data(), string_value.size()};
StringRef inserted_value = copyStringInArena(string_value_ref);
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container.back() = inserted_value;
}
else
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container.back() = column_value.get<NearestFieldType<ElementType>>();
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});
}
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++size;
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}
else
{
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if (cell.key != key)
{
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if constexpr (std::is_same_v<KeyType, StringRef>)
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{
char * data = const_cast<char *>(cell.key.data);
arena.free(data, cell.key.size);
cell.key = copyStringInArena(key);
}
else
cell.key = key;
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}
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/// Put values into existing index
size_t index_to_use = cell.element_index;
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for (size_t attribute_index = 0; attribute_index < columns.size(); ++attribute_index)
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{
auto & column = columns[attribute_index];
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getAttributeContainer(attribute_index, [&](auto & container)
{
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using ElementType = std::decay_t<decltype(container[0])>;
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column->get(key_index, column_value);
if constexpr (std::is_same_v<ElementType, Field>)
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container[index_to_use] = column_value;
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else if constexpr (std::is_same_v<ElementType, StringRef>)
{
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const String & string_value = column_value.get<String>();
StringRef string_ref_value = StringRef {string_value.data(), string_value.size()};
StringRef inserted_value = copyStringInArena(string_ref_value);
if (!cell_was_default)
{
StringRef previous_value = container[index_to_use];
arena.free(const_cast<char *>(previous_value.data), previous_value.size);
}
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container[index_to_use] = inserted_value;
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}
else
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container[index_to_use] = column_value.get<NearestFieldType<ElementType>>();
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});
}
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}
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setCellDeadline(cell, now);
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}
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}
void insertDefaultKeysImpl(const PaddedPODArray<KeyType> & keys)
{
const auto now = std::chrono::system_clock::now();
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size_t keys_size = keys.size();
for (size_t key_index = 0; key_index < keys_size; ++key_index)
{
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auto key = keys[key_index];
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size_t cell_index = getCellIndexForInsert(key);
auto & cell = cells[cell_index];
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bool was_inserted = cell.deadline == 0;
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bool cell_was_default = cell.is_default;
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cell.is_default = true;
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if (was_inserted)
{
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if constexpr (std::is_same_v<KeyType, StringRef>)
cell.key = copyStringInArena(key);
else
cell.key = key;
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for (size_t attribute_index = 0; attribute_index < attributes.size(); ++attribute_index)
{
getAttributeContainer(attribute_index, [&](auto & container)
{
container.emplace_back();
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cell.element_index = container.size() - 1;
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});
}
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++size;
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}
else
{
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for (size_t attribute_index = 0; attribute_index < attributes.size(); ++attribute_index)
{
getAttributeContainer(attribute_index, [&](const auto & container)
{
using ElementType = std::decay_t<decltype(container[0])>;
if constexpr (std::is_same_v<ElementType, StringRef>)
{
if (!cell_was_default)
{
StringRef previous_value = container[cell.element_index];
arena.free(const_cast<char *>(previous_value.data), previous_value.size);
}
}
});
}
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if (cell.key != key)
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{
if constexpr (std::is_same_v<KeyType, StringRef>)
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{
char * data = const_cast<char *>(cell.key.data);
arena.free(data, cell.key.size);
cell.key = copyStringInArena(key);
}
else
cell.key = key;
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}
}
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setCellDeadline(cell, now);
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}
}
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PaddedPODArray<KeyType> getCachedKeysImpl() const
{
PaddedPODArray<KeyType> result;
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result.reserve(size);
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for (auto & cell : cells)
{
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if (cell.deadline == 0)
continue;
if (cell.is_default)
continue;
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result.emplace_back(cell.key);
}
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return result;
}
template <typename GetContainerFunc>
void getAttributeContainer(size_t attribute_index, GetContainerFunc && func)
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{
auto & attribute = attributes[attribute_index];
auto & attribute_type = attribute.type;
if (unlikely(attribute.is_complex_type))
{
auto & container = std::get<std::vector<Field>>(attribute.attribute_container);
std::forward<GetContainerFunc>(func)(container);
}
else
{
auto type_call = [&](const auto & dictionary_attribute_type)
{
using Type = std::decay_t<decltype(dictionary_attribute_type)>;
using AttributeType = typename Type::AttributeType;
using ValueType = DictionaryValueType<AttributeType>;
auto & container = std::get<PaddedPODArray<ValueType>>(attribute.attribute_container);
std::forward<GetContainerFunc>(func)(container);
};
callOnDictionaryAttributeType(attribute_type, type_call);
}
}
template <typename GetContainerFunc>
void getAttributeContainer(size_t attribute_index, GetContainerFunc && func) const
{
return const_cast<std::decay_t<decltype(*this)> *>(this)->template getAttributeContainer(attribute_index, std::forward<GetContainerFunc>(func));
}
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StringRef copyStringInArena(StringRef value_to_copy)
{
size_t value_to_copy_size = value_to_copy.size;
char * place_for_key = arena.alloc(value_to_copy_size);
memcpy(reinterpret_cast<void *>(place_for_key), reinterpret_cast<const void *>(value_to_copy.data), value_to_copy_size);
StringRef updated_value{place_for_key, value_to_copy_size};
return updated_value;
}
void setup(const DictionaryStructure & dictionary_structure)
{
/// For each dictionary attribute create storage attribute
/// For simple attributes create PODArray, for complex vector of Fields
attributes.reserve(dictionary_structure.attributes.size());
for (const auto & dictionary_attribute : dictionary_structure.attributes)
{
auto attribute_type = dictionary_attribute.underlying_type;
auto type_call = [&](const auto & dictionary_attribute_type)
{
using Type = std::decay_t<decltype(dictionary_attribute_type)>;
using AttributeType = typename Type::AttributeType;
using ValueType = DictionaryValueType<AttributeType>;
attributes.emplace_back();
auto & last_attribute = attributes.back();
last_attribute.type = attribute_type;
last_attribute.is_complex_type = dictionary_attribute.is_nullable || dictionary_attribute.is_array;
if (dictionary_attribute.is_nullable)
last_attribute.attribute_container = std::vector<Field>();
else
last_attribute.attribute_container = PaddedPODArray<ValueType>();
};
callOnDictionaryAttributeType(attribute_type, type_call);
}
}
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using TimePoint = std::chrono::system_clock::time_point;
struct Cell
{
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KeyType key;
size_t element_index;
bool is_default;
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time_t deadline;
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};
struct Attribute
{
AttributeUnderlyingType type;
bool is_complex_type;
std::variant<
PaddedPODArray<UInt8>,
PaddedPODArray<UInt16>,
PaddedPODArray<UInt32>,
PaddedPODArray<UInt64>,
PaddedPODArray<UInt128>,
PaddedPODArray<Int8>,
PaddedPODArray<Int16>,
PaddedPODArray<Int32>,
PaddedPODArray<Int64>,
PaddedPODArray<Decimal32>,
PaddedPODArray<Decimal64>,
PaddedPODArray<Decimal128>,
PaddedPODArray<Float32>,
PaddedPODArray<Float64>,
PaddedPODArray<StringRef>,
std::vector<Field>> attribute_container;
};
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CacheDictionaryStorageConfiguration configuration;
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pcg64 rnd_engine;
size_t size_overlap_mask = 0;
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size_t size = 0;
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PaddedPODArray<Cell> cells;
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ArenaWithFreeLists arena;
std::vector<Attribute> attributes;
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inline void setCellDeadline(Cell & cell, TimePoint now)
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{
if (configuration.lifetime.min_sec == 0 && configuration.lifetime.max_sec == 0)
{
/// This maybe not obvious, but when we define is this cell is expired or expired permanently, we add strict_max_lifetime_seconds
/// to the expiration time. And it overflows pretty well.
auto deadline = std::chrono::time_point<std::chrono::system_clock>::max() - 2 * std::chrono::seconds(configuration.strict_max_lifetime_seconds);
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cell.deadline = std::chrono::system_clock::to_time_t(deadline);
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return;
}
size_t min_sec_lifetime = configuration.lifetime.min_sec;
size_t max_sec_lifetime = configuration.lifetime.max_sec;
std::uniform_int_distribution<UInt64> distribution{min_sec_lifetime, max_sec_lifetime};
auto deadline = now + std::chrono::seconds(distribution(rnd_engine));
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cell.deadline = std::chrono::system_clock::to_time_t(deadline);
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}
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inline size_t getCellIndex(const KeyType key) const
{
const size_t hash = DefaultHash<KeyType>()(key);
const size_t index = hash & size_overlap_mask;
return index;
}
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using KeyStateAndCellIndex = std::pair<KeyState::State, size_t>;
inline KeyStateAndCellIndex getKeyStateAndCellIndex(const KeyType key, const time_t now) const
{
size_t place_value = getCellIndex(key);
const size_t place_value_end = place_value + max_collision_length;
time_t max_lifetime_seconds = static_cast<time_t>(configuration.strict_max_lifetime_seconds);
for (; place_value < place_value_end; ++place_value)
{
const auto cell_place_value = place_value & size_overlap_mask;
const auto & cell = cells[cell_place_value];
if (cell.key != key)
continue;
if (unlikely(now > cell.deadline + max_lifetime_seconds))
return std::make_pair(KeyState::not_found, cell_place_value);
if (unlikely(now > cell.deadline))
return std::make_pair(KeyState::expired, cell_place_value);
return std::make_pair(KeyState::found, cell_place_value);
}
return std::make_pair(KeyState::not_found, place_value & size_overlap_mask);
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}
inline size_t getCellIndexForInsert(const KeyType & key) const
{
size_t place_value = getCellIndex(key);
const size_t place_value_end = place_value + max_collision_length;
size_t oldest_place_value = place_value;
time_t oldest_time = std::numeric_limits<time_t>::max();
for (; place_value < place_value_end; ++place_value)
{
const size_t cell_place_value = place_value & size_overlap_mask;
const Cell cell = cells[cell_place_value];
if (cell.deadline == 0)
return cell_place_value;
if (cell.key == key)
return cell_place_value;
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if (cell.deadline < oldest_time)
{
oldest_time = cell.deadline;
oldest_place_value = cell_place_value;
}
}
return oldest_place_value;
}
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};
}