thevar1able/ClickHouse
1
0
Fork 0
mirror of https://github.com/ClickHouse/ClickHouse.git synced 2024-11-11 01:54:55 +00:00
Code Issues Packages Projects Releases Wiki Activity
b64633e2a0
ClickHouse/dbms/include/DB/Core/Field.h
Alexey Milovidov a907109ff8 Field: removed useless hash function [#METR-2807].
2013-11-02 22:20:58 +00:00

819 lines
24 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

#pragma once
#include <vector>
#include <tr1/type_traits>
#include <tr1/functional>
#include <boost/static_assert.hpp>
#include <mysqlxx/Date.h>
#include <mysqlxx/DateTime.h>
#include <mysqlxx/Manip.h>
#include <DB/Core/Types.h>
#include <DB/Core/Exception.h>
#include <DB/Core/ErrorCodes.h>
#include <DB/IO/ReadHelpers.h>
#include <DB/IO/WriteHelpers.h>
#include <DB/IO/WriteBufferFromString.h>
namespace DB
{
class Field;
typedef std::vector<Field> Array; /// Значение типа "массив"
using Poco::SharedPtr;
/** 32 хватает с запасом (достаточно 28), но выбрано круглое число,
* чтобы арифметика при использовании массивов из Field была проще (не содержала умножения).
*/
#define DBMS_TOTAL_FIELD_SIZE 32
/** Discriminated union из нескольких типов.
* Сделан для замены boost::variant:
* является не обобщённым,
* зато несколько более эффективным, и более простым.
*
* Используется для представления единичного значения одного из нескольких типов в оперативке.
* Внимание! Предпочтительно вместо единичных значений хранить кусочки столбцов. См. Column.h
*/
class __attribute__((aligned(DBMS_TOTAL_FIELD_SIZE))) Field
{
public:
struct Types
{
/// Идентификатор типа.
enum Which
{
Null = 0,
UInt64 = 1,
Int64 = 2,
Float64 = 3,
/// не POD типы. Для них предполагается relocatable.
String = 16,
Array = 17,
};
static const int MIN_NON_POD = 16;
static const char * toString(Which which)
{
switch (which)
{
case Null: return "Null";
case UInt64: return "UInt64";
case Int64: return "Int64";
case Float64: return "Float64";
case String: return "String";
case Array: return "Array";
default:
throw Exception("Bad type of Field", ErrorCodes::BAD_TYPE_OF_FIELD);
}
}
};
/// Позволяет получить идентификатор для типа или наоборот.
template <typename T> struct TypeToEnum;
template <Types::Which which> struct EnumToType;
Field()
: which(Types::Null)
{
// std::cerr << "Field()" << std::endl;
}
/** Не смотря на наличие шаблонного конструктора, этот конструктор всё-равно нужен,
* так как при его отсутствии, компилятор всё-равно сгенерирует конструктор по-умолчанию.
*/
Field(const Field & rhs)
{
// std::cerr << this << " Field::Field(const Field &)" << std::endl;
create(rhs);
}
Field & operator= (const Field & rhs)
{
// std::cerr << this << " Field::operator=(const Field &)" << std::endl;
destroy();
create(rhs);
return *this;
}
template <typename T>
Field(const T & rhs)
{
// std::cerr << this << " Field::Field(" << Types::toString(TypeToEnum<T>::value) << ")" << std::endl;
create(rhs);
}
/// Создать строку inplace.
Field(const char * data, size_t size)
{
create(data, size);
}
Field(const unsigned char * data, size_t size)
{
create(data, size);
}
void assignString(const char * data, size_t size)
{
destroy();
create(data, size);
}
void assignString(const unsigned char * data, size_t size)
{
destroy();
create(data, size);
}
template <typename T>
Field & operator= (const T & rhs)
{
// std::cerr << this << " Field::operator=(" << Types::toString(TypeToEnum<T>::value) << ")" << std::endl;
destroy();
create(rhs);
return *this;
}
~Field()
{
// std::cerr << this << " Field::~Field()" << std::endl;
destroy();
}
Types::Which getType() const { return which; }
const char * getTypeName() const { return Types::toString(which); }
bool isNull() const { return which == Types::Null; }
template <typename T> T & get()
{
typedef typename std::tr1::remove_reference<T>::type TWithoutRef;
TWithoutRef * __attribute__((__may_alias__)) ptr = reinterpret_cast<TWithoutRef*>(storage);
return *ptr;
};
template <typename T> const T & get() const
{
typedef typename std::tr1::remove_reference<T>::type TWithoutRef;
const TWithoutRef * __attribute__((__may_alias__)) ptr = reinterpret_cast<const TWithoutRef*>(storage);
return *ptr;
};
template <typename T> T & safeGet()
{
const Types::Which requested = TypeToEnum<typename std::tr1::remove_cv<typename std::tr1::remove_reference<T>::type>::type>::value;
if (which != requested)
throw Exception("Bad get: has " + std::string(getTypeName()) + ", requested " + std::string(Types::toString(requested)), ErrorCodes::BAD_GET);
return get<T>();
}
template <typename T> const T & safeGet() const
{
const Types::Which requested = TypeToEnum<typename std::tr1::remove_cv<typename std::tr1::remove_reference<T>::type>::type>::value;
if (which != requested)
throw Exception("Bad get: has " + std::string(getTypeName()) + ", requested " + std::string(Types::toString(requested)), ErrorCodes::BAD_GET);
return get<T>();
}
bool operator< (const Field & rhs) const
{
if (which < rhs.which)
return true;
if (which > rhs.which)
return false;
switch (which)
{
case Types::Null: return false;
case Types::UInt64: return get<UInt64>() < rhs.get<UInt64>();
case Types::Int64: return get<Int64>() < rhs.get<Int64>();
case Types::Float64: return get<Float64>() < rhs.get<Float64>();
case Types::String: return get<String>() < rhs.get<String>();
case Types::Array: return get<Array>() < rhs.get<Array>();
default:
throw Exception("Bad type of Field", ErrorCodes::BAD_TYPE_OF_FIELD);
}
}
bool operator> (const Field & rhs) const
{
return rhs < *this;
}
bool operator<= (const Field & rhs) const
{
if (which < rhs.which)
return true;
if (which > rhs.which)
return false;
switch (which)
{
case Types::Null: return true;
case Types::UInt64: return get<UInt64>() <= rhs.get<UInt64>();
case Types::Int64: return get<Int64>() <= rhs.get<Int64>();
case Types::Float64: return get<Float64>() <= rhs.get<Float64>();
case Types::String: return get<String>() <= rhs.get<String>();
case Types::Array: return get<Array>() <= rhs.get<Array>();
default:
throw Exception("Bad type of Field", ErrorCodes::BAD_TYPE_OF_FIELD);
}
}
bool operator>= (const Field & rhs) const
{
return rhs <= *this;
}
bool operator== (const Field & rhs) const
{
if (which != rhs.which)
return false;
switch (which)
{
case Types::Null: return true;
case Types::UInt64:
case Types::Int64:
case Types::Float64: return get<UInt64>() == rhs.get<UInt64>();
case Types::String: return get<String>() == rhs.get<String>();
case Types::Array: return get<Array>() == rhs.get<Array>();
default:
throw Exception("Bad type of Field", ErrorCodes::BAD_TYPE_OF_FIELD);
}
}
bool operator!= (const Field & rhs) const
{
return !(*this == rhs);
}
private:
/// Хватает с запасом
static const size_t storage_size = DBMS_TOTAL_FIELD_SIZE - sizeof(Types::Which);
BOOST_STATIC_ASSERT(storage_size >= sizeof(Null));
BOOST_STATIC_ASSERT(storage_size >= sizeof(UInt64));
BOOST_STATIC_ASSERT(storage_size >= sizeof(Int64));
BOOST_STATIC_ASSERT(storage_size >= sizeof(Float64));
BOOST_STATIC_ASSERT(storage_size >= sizeof(String));
BOOST_STATIC_ASSERT(storage_size >= sizeof(Array));
char storage[storage_size] __attribute__((aligned(8)));
Types::Which which;
template <typename T>
void create(const T & x)
{
which = TypeToEnum<T>::value;
// std::cerr << this << " Creating " << getTypeName() << std::endl;
T * __attribute__((__may_alias__)) ptr = reinterpret_cast<T*>(storage);
new (ptr) T(x);
}
void create(const Null & x)
{
which = Types::Null;
// std::cerr << this << " Creating " << getTypeName() << std::endl;
}
void create(const Field & x)
{
// std::cerr << this << " Creating Field" << std::endl;
switch (x.which)
{
case Types::Null: create(Null()); break;
case Types::UInt64: create(x.get<UInt64>()); break;
case Types::Int64: create(x.get<Int64>()); break;
case Types::Float64: create(x.get<Float64>()); break;
case Types::String: create(x.get<String>()); break;
case Types::Array: create(x.get<Array>()); break;
}
}
void create(const char * data, size_t size)
{
which = Types::String;
String * __attribute__((__may_alias__)) ptr = reinterpret_cast<String*>(storage);
new (ptr) String(data, size);
}
void create(const unsigned char * data, size_t size)
{
create(reinterpret_cast<const char *>(data), size);
}
__attribute__((__always_inline__)) void destroy()
{
// std::cerr << this << " Destroying " << getTypeName() << std::endl;
if (which < Types::MIN_NON_POD)
return;
switch (which)
{
case Types::String:
destroy<String>();
break;
case Types::Array:
destroy<Array>();
break;
default:
break;
}
}
template <typename T>
void destroy()
{
T * __attribute__((__may_alias__)) ptr = reinterpret_cast<T*>(storage);
ptr->~T();
}
};
template <> struct Field::TypeToEnum<Null> { static const Types::Which value = Types::Null; };
template <> struct Field::TypeToEnum<UInt64> { static const Types::Which value = Types::UInt64; };
template <> struct Field::TypeToEnum<Int64> { static const Types::Which value = Types::Int64; };
template <> struct Field::TypeToEnum<Float64> { static const Types::Which value = Types::Float64; };
template <> struct Field::TypeToEnum<String> { static const Types::Which value = Types::String; };
template <> struct Field::TypeToEnum<Array> { static const Types::Which value = Types::Array; };
template <> struct Field::EnumToType<Field::Types::Null> { typedef Null Type; };
template <> struct Field::EnumToType<Field::Types::UInt64> { typedef UInt64 Type; };
template <> struct Field::EnumToType<Field::Types::Int64> { typedef Int64 Type; };
template <> struct Field::EnumToType<Field::Types::Float64> { typedef Float64 Type; };
template <> struct Field::EnumToType<Field::Types::String> { typedef String Type; };
template <> struct Field::EnumToType<Field::Types::Array> { typedef Array Type; };
template <typename T>
T get(const Field & field)
{
return field.template get<T>();
}
template <typename T>
T get(Field & field)
{
return field.template get<T>();
}
template <typename T>
T safeGet(const Field & field)
{
return field.template safeGet<T>();
}
template <typename T>
T safeGet(Field & field)
{
return field.template safeGet<T>();
}
/** StaticVisitor (его наследники) - класс с перегруженными для разных типов операторами ().
* Вызвать visitor для field можно с помощью функции apply_visitor.
* Также поддерживается visitor, в котором оператор () принимает два аргумента.
*/
template <typename R = void>
struct StaticVisitor
{
typedef R ResultType;
};
template <typename Visitor, typename F>
typename Visitor::ResultType apply_visitor_impl(Visitor & visitor, F & field)
{
switch (field.getType())
{
case Field::Types::Null: return visitor(field.template get<Null>());
case Field::Types::UInt64: return visitor(field.template get<UInt64>());
case Field::Types::Int64: return visitor(field.template get<Int64>());
case Field::Types::Float64: return visitor(field.template get<Float64>());
case Field::Types::String: return visitor(field.template get<String>());
case Field::Types::Array: return visitor(field.template get<Array>());
default:
throw Exception("Bad type of Field", ErrorCodes::BAD_TYPE_OF_FIELD);
}
}
/** Эти штуки нужны, чтобы принимать временный объект по константной ссылке.
* В шаблон выше, типы форвардятся уже с const-ом.
*/
template <typename Visitor>
typename Visitor::ResultType apply_visitor(const Visitor & visitor, Field & field)
{
return apply_visitor_impl(visitor, field);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(const Visitor & visitor, const Field & field)
{
return apply_visitor_impl(visitor, field);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(Visitor & visitor, Field & field)
{
return apply_visitor_impl(visitor, field);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(Visitor & visitor, const Field & field)
{
return apply_visitor_impl(visitor, field);
}
template <typename Visitor, typename F1, typename F2>
typename Visitor::ResultType apply_binary_visitor_impl2(Visitor & visitor, F1 & field1, F2 & field2)
{
switch (field2.getType())
{
case Field::Types::Null: return visitor(field1, field2.template get<Null>());
case Field::Types::UInt64: return visitor(field1, field2.template get<UInt64>());
case Field::Types::Int64: return visitor(field1, field2.template get<Int64>());
case Field::Types::Float64: return visitor(field1, field2.template get<Float64>());
case Field::Types::String: return visitor(field1, field2.template get<String>());
case Field::Types::Array: return visitor(field1, field2.template get<Array>());
default:
throw Exception("Bad type of Field", ErrorCodes::BAD_TYPE_OF_FIELD);
}
}
template <typename Visitor, typename F1, typename F2>
typename Visitor::ResultType apply_binary_visitor_impl1(Visitor & visitor, F1 & field1, F2 & field2)
{
switch (field1.getType())
{
case Field::Types::Null: return apply_binary_visitor_impl2(visitor, field1.template get<Null>(), field2);
case Field::Types::UInt64: return apply_binary_visitor_impl2(visitor, field1.template get<UInt64>(), field2);
case Field::Types::Int64: return apply_binary_visitor_impl2(visitor, field1.template get<Int64>(), field2);
case Field::Types::Float64: return apply_binary_visitor_impl2(visitor, field1.template get<Float64>(), field2);
case Field::Types::String: return apply_binary_visitor_impl2(visitor, field1.template get<String>(), field2);
case Field::Types::Array: return apply_binary_visitor_impl2(visitor, field1.template get<Array>(), field2);
default:
throw Exception("Bad type of Field", ErrorCodes::BAD_TYPE_OF_FIELD);
}
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(Visitor & visitor, Field & field1, Field & field2)
{
return apply_binary_visitor_impl1(visitor, field1, field2);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(Visitor & visitor, Field & field1, const Field & field2)
{
return apply_binary_visitor_impl1(visitor, field1, field2);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(Visitor & visitor, const Field & field1, Field & field2)
{
return apply_binary_visitor_impl1(visitor, field1, field2);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(Visitor & visitor, const Field & field1, const Field & field2)
{
return apply_binary_visitor_impl1(visitor, field1, field2);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(const Visitor & visitor, Field & field1, Field & field2)
{
return apply_binary_visitor_impl1(visitor, field1, field2);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(const Visitor & visitor, Field & field1, const Field & field2)
{
return apply_binary_visitor_impl1(visitor, field1, field2);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(const Visitor & visitor, const Field & field1, Field & field2)
{
return apply_binary_visitor_impl1(visitor, field1, field2);
}
template <typename Visitor>
typename Visitor::ResultType apply_visitor(const Visitor & visitor, const Field & field1, const Field & field2)
{
return apply_binary_visitor_impl1(visitor, field1, field2);
}
template <> struct TypeName<Array> { static std::string get() { return "Array"; } };
/** Возвращает строковый дамп типа */
class FieldVisitorDump : public StaticVisitor<String>
{
private:
template <typename T>
static inline String formatQuotedWithPrefix(T x, const char * prefix)
{
String res;
WriteBufferFromString wb(res);
wb.write(prefix, strlen(prefix));
writeQuoted(x, wb);
return res;
}
public:
String operator() (const Null & x) const { return "NULL"; }
String operator() (const UInt64 & x) const { return formatQuotedWithPrefix(x, "UInt64_"); }
String operator() (const Int64 & x) const { return formatQuotedWithPrefix(x, "Int64_"); }
String operator() (const Float64 & x) const { return formatQuotedWithPrefix(x, "Float64_"); }
String operator() (const String & x) const
{
String res;
WriteBufferFromString wb(res);
writeQuoted(x, wb);
return res;
}
String operator() (const Array & x) const
{
String res;
WriteBufferFromString wb(res);
FieldVisitorDump visitor;
wb.write("Array_[", 7);
for (Array::const_iterator it = x.begin(); it != x.end(); ++it)
{
if (it != x.begin())
wb.write(", ", 2);
writeString(apply_visitor(visitor, *it), wb);
}
writeChar(']', wb);
return res;
}
};
/** Выводит текстовое представление типа, как литерала в SQL запросе */
class FieldVisitorToString : public StaticVisitor<String>
{
private:
template <typename T>
static inline String formatQuoted(T x)
{
String res;
WriteBufferFromString wb(res);
writeQuoted(x, wb);
return res;
}
public:
String operator() (const Null & x) const { return "NULL"; }
String operator() (const UInt64 & x) const { return formatQuoted(x); }
String operator() (const Int64 & x) const { return formatQuoted(x); }
String operator() (const Float64 & x) const { return formatQuoted(x); }
String operator() (const String & x) const { return formatQuoted(x); }
String operator() (const Array & x) const
{
String res;
WriteBufferFromString wb(res);
FieldVisitorToString visitor;
writeChar('[', wb);
for (Array::const_iterator it = x.begin(); it != x.end(); ++it)
{
if (it != x.begin())
wb.write(", ", 2);
writeString(apply_visitor(visitor, *it), wb);
}
writeChar(']', wb);
return res;
}
};
/** Числовой тип преобразует в указанный. */
template <typename T>
class FieldVisitorConvertToNumber : public StaticVisitor<T>
{
public:
T operator() (const Null & x) const
{
throw Exception("Cannot convert NULL to " + TypeName<T>::get(), ErrorCodes::CANNOT_CONVERT_TYPE);
}
T operator() (const String & x) const
{
throw Exception("Cannot convert String to " + TypeName<T>::get(), ErrorCodes::CANNOT_CONVERT_TYPE);
}
T operator() (const Array & x) const
{
throw Exception("Cannot convert Array to " + TypeName<T>::get(), ErrorCodes::CANNOT_CONVERT_TYPE);
}
T operator() (const UInt64 & x) const { return x; }
T operator() (const Int64 & x) const { return x; }
T operator() (const Float64 & x) const { return x; }
};
template <typename T> struct NearestFieldType;
template <> struct NearestFieldType<UInt8> { typedef UInt64 Type; };
template <> struct NearestFieldType<UInt16> { typedef UInt64 Type; };
template <> struct NearestFieldType<UInt32> { typedef UInt64 Type; };
template <> struct NearestFieldType<UInt64> { typedef UInt64 Type; };
template <> struct NearestFieldType<Int8> { typedef Int64 Type; };
template <> struct NearestFieldType<Int16> { typedef Int64 Type; };
template <> struct NearestFieldType<Int32> { typedef Int64 Type; };
template <> struct NearestFieldType<Int64> { typedef Int64 Type; };
template <> struct NearestFieldType<Float32> { typedef Float64 Type; };
template <> struct NearestFieldType<Float64> { typedef Float64 Type; };
template <> struct NearestFieldType<String> { typedef String Type; };
template <> struct NearestFieldType<Array> { typedef Array Type; };
template <> struct NearestFieldType<bool> { typedef UInt64 Type; };
template <typename T>
typename NearestFieldType<T>::Type nearestFieldType(const T & x)
{
return typename NearestFieldType<T>::Type(x);
}
}
/// Заглушки, чтобы DBObject-ы с полем типа Array компилировались.
namespace mysqlxx
{
inline std::ostream & operator<< (mysqlxx::EscapeManipResult res, const DB::Array & value)
{
return res.ostr << apply_visitor(DB::FieldVisitorToString(), value);
}
inline std::ostream & operator<< (mysqlxx::QuoteManipResult res, const DB::Array & value)
{
throw Poco::Exception("Cannot quote Array with mysqlxx::quote.");
}
inline std::istream & operator>> (mysqlxx::UnEscapeManipResult res, DB::Array & value)
{
throw Poco::Exception("Cannot unescape Array with mysqlxx::unescape.");
}
inline std::istream & operator>> (mysqlxx::UnQuoteManipResult res, DB::Array & value)
{
throw Poco::Exception("Cannot unquote Array with mysqlxx::unquote.");
}
}
namespace DB
{
class ReadBuffer;
class WriteBuffer;
/// Предполагается что у всех элементов массива одинаковый тип.
inline void readBinary(Array & x, ReadBuffer & buf)
{
size_t size;
UInt8 type;
DB::readBinary(type, buf);
DB::readBinary(size, buf);
for (size_t index = 0; index < size; ++index)
{
switch (type)
{
case Field::Types::Null:
{
x.push_back(DB::Field());
break;
}
case Field::Types::UInt64:
{
UInt64 value;
DB::readVarUInt(value, buf);
x.push_back(value);
break;
}
case Field::Types::Int64:
{
Int64 value;
DB::readVarInt(value, buf);
x.push_back(value);
break;
}
case Field::Types::Float64:
{
Float64 value;
DB::readFloatBinary(value, buf);
x.push_back(value);
break;
}
case Field::Types::String:
{
std::string value;
DB::readStringBinary(value, buf);
x.push_back(value);
break;
}
case Field::Types::Array:
{
Array value;
DB::readBinary(value, buf);
x.push_back(value);
break;
}
};
}
}
inline void readText(Array & x, ReadBuffer & buf) { throw Exception("Cannot read Array.", ErrorCodes::NOT_IMPLEMENTED); }
inline void readQuoted(Array & x, ReadBuffer & buf) { throw Exception("Cannot read Array.", ErrorCodes::NOT_IMPLEMENTED); }
/// Предполагается что у всех элементов массива одинаковый тип.
inline void writeBinary(const Array & x, WriteBuffer & buf)
{
UInt8 type = Field::Types::Null;
size_t size = x.size();
if (size)
type = x.front().getType();
DB::writeBinary(type, buf);
DB::writeBinary(size, buf);
for (Array::const_iterator it = x.begin(); it != x.end(); ++it)
{
switch (type)
{
case Field::Types::Null: break;
case Field::Types::UInt64:
{
DB::writeVarUInt(get<UInt64>(*it), buf);
break;
}
case Field::Types::Int64:
{
DB::writeVarInt(get<Int64>(*it), buf);
break;
}
case Field::Types::Float64:
{
DB::writeFloatBinary(get<Float64>(*it), buf);
break;
}
case Field::Types::String:
{
DB::writeStringBinary(get<std::string>(*it), buf);
break;
}
case Field::Types::Array:
{
DB::writeBinary(get<Array>(*it), buf);
break;
}
};
}
}
inline void writeText(const Array & x, WriteBuffer & buf)
{
DB::String res = apply_visitor(DB::FieldVisitorToString(), DB::Field(x));
buf.write(res.data(), res.size());
}
inline void writeQuoted(const Array & x, WriteBuffer & buf) { throw Exception("Cannot write Array quoted.", ErrorCodes::NOT_IMPLEMENTED); }
}
#undef DBMS_TOTAL_FIELD_SIZE
Reference in New Issue View Git Blame Copy Permalink