#pragma once #include #include #include #include #include namespace DB { class Field; class ReadBuffer; class WriteBuffer; /** One setting for any type. * Stores a value within itself, as well as a flag - whether the value was changed. * This is done so that you can send to the remote servers only changed settings (or explicitly specified in the config) values. * That is, if the configuration was not specified in the config and was not dynamically changed, it is not sent to the remote server, * and the remote server will use its default value. */ template struct SettingInt { IntType value; bool changed = false; SettingInt(IntType x = 0) : value(x) {} operator IntType() const { return value; } SettingInt & operator= (IntType x) { set(x); return *this; } /// Serialize to a test string. String toString() const; /// Serialize to binary stream suitable for transfer over network. void write(WriteBuffer & buf) const; void set(IntType x); /// Read from SQL literal. void set(const Field & x); /// Read from text string. void set(const String & x); /// Read from binary stream. void set(ReadBuffer & buf); }; using SettingUInt64 = SettingInt; using SettingInt64 = SettingInt; using SettingBool = SettingUInt64; /** Unlike SettingUInt64, supports the value of 'auto' - the number of processor cores without taking into account SMT. * A value of 0 is also treated as auto. * When serializing, `auto` is written in the same way as 0. */ struct SettingMaxThreads { UInt64 value; bool is_auto; bool changed = false; SettingMaxThreads(UInt64 x = 0) : value(x ? x : getAutoValue()), is_auto(x == 0) {} operator UInt64() const { return value; } SettingMaxThreads & operator= (UInt64 x) { set(x); return *this; } String toString() const; void set(UInt64 x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; void setAuto(); UInt64 getAutoValue() const; /// Executed once for all time. Executed from one thread. UInt64 getAutoValueImpl() const; }; struct SettingSeconds { Poco::Timespan value; bool changed = false; SettingSeconds(UInt64 seconds = 0) : value(seconds, 0) {} operator Poco::Timespan() const { return value; } SettingSeconds & operator= (const Poco::Timespan & x) { set(x); return *this; } Poco::Timespan::TimeDiff totalSeconds() const { return value.totalSeconds(); } String toString() const; void set(const Poco::Timespan & x); void set(UInt64 x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; struct SettingMilliseconds { Poco::Timespan value; bool changed = false; SettingMilliseconds(UInt64 milliseconds = 0) : value(milliseconds * 1000) {} operator Poco::Timespan() const { return value; } SettingMilliseconds & operator= (const Poco::Timespan & x) { set(x); return *this; } Poco::Timespan::TimeDiff totalMilliseconds() const { return value.totalMilliseconds(); } String toString() const; void set(const Poco::Timespan & x); void set(UInt64 x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; struct SettingFloat { float value; bool changed = false; SettingFloat(float x = 0) : value(x) {} operator float() const { return value; } SettingFloat & operator= (float x) { set(x); return *this; } String toString() const; void set(float x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; enum class LoadBalancing { /// among replicas with a minimum number of errors selected randomly RANDOM = 0, /// a replica is selected among the replicas with the minimum number of errors /// with the minimum number of distinguished characters in the replica name and local hostname NEAREST_HOSTNAME, /// replicas are walked through strictly in order; the number of errors does not matter IN_ORDER, }; struct SettingLoadBalancing { LoadBalancing value; bool changed = false; SettingLoadBalancing(LoadBalancing x) : value(x) {} operator LoadBalancing() const { return value; } SettingLoadBalancing & operator= (LoadBalancing x) { set(x); return *this; } static LoadBalancing getLoadBalancing(const String & s); String toString() const; void set(LoadBalancing x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; enum class JoinStrictness { Unspecified = 0, /// Query JOIN without strictness will throw Exception. ALL, /// Query JOIN without strictness -> ALL JOIN ... ANY, /// Query JOIN without strictness -> ANY JOIN ... }; struct SettingJoinStrictness { JoinStrictness value; bool changed = false; SettingJoinStrictness(JoinStrictness x) : value(x) {} operator JoinStrictness() const { return value; } SettingJoinStrictness & operator= (JoinStrictness x) { set(x); return *this; } static JoinStrictness getJoinStrictness(const String & s); String toString() const; void set(JoinStrictness x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; /// Which rows should be included in TOTALS. enum class TotalsMode { BEFORE_HAVING = 0, /// Count HAVING for all read rows; /// including those not in max_rows_to_group_by /// and have not passed HAVING after grouping. AFTER_HAVING_INCLUSIVE = 1, /// Count on all rows except those that have not passed HAVING; /// that is, to include in TOTALS all the rows that did not pass max_rows_to_group_by. AFTER_HAVING_EXCLUSIVE = 2, /// Include only the rows that passed and max_rows_to_group_by, and HAVING. AFTER_HAVING_AUTO = 3, /// Automatically select between INCLUSIVE and EXCLUSIVE, }; struct SettingTotalsMode { TotalsMode value; bool changed = false; SettingTotalsMode(TotalsMode x) : value(x) {} operator TotalsMode() const { return value; } SettingTotalsMode & operator= (TotalsMode x) { set(x); return *this; } static TotalsMode getTotalsMode(const String & s); String toString() const; void set(TotalsMode x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; template struct SettingOverflowMode { OverflowMode value; bool changed = false; SettingOverflowMode(OverflowMode x = OverflowMode::THROW) : value(x) {} operator OverflowMode() const { return value; } SettingOverflowMode & operator= (OverflowMode x) { set(x); return *this; } static OverflowMode getOverflowModeForGroupBy(const String & s); static OverflowMode getOverflowMode(const String & s); String toString() const; void set(OverflowMode x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; struct SettingCompressionMethod { CompressionMethod value; bool changed = false; SettingCompressionMethod(CompressionMethod x = CompressionMethod::LZ4) : value(x) {} operator CompressionMethod() const { return value; } SettingCompressionMethod & operator= (CompressionMethod x) { set(x); return *this; } static CompressionMethod getCompressionMethod(const String & s); String toString() const; void set(CompressionMethod x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; /// The setting for executing distributed subqueries inside IN or JOIN sections. enum class DistributedProductMode { DENY = 0, /// Disable LOCAL, /// Convert to local query GLOBAL, /// Convert to global query ALLOW /// Enable }; struct SettingDistributedProductMode { DistributedProductMode value; bool changed = false; SettingDistributedProductMode(DistributedProductMode x) : value(x) {} operator DistributedProductMode() const { return value; } SettingDistributedProductMode & operator= (DistributedProductMode x) { set(x); return *this; } static DistributedProductMode getDistributedProductMode(const String & s); String toString() const; void set(DistributedProductMode x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; struct SettingString { String value; bool changed = false; SettingString(const String & x = String{}) : value(x) {} operator String() const { return value; } SettingString & operator= (const String & x) { set(x); return *this; } String toString() const; void set(const String & x); void set(const Field & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; struct SettingChar { private: void checkStringIsACharacter(const String & x) const; public: char value; bool changed = false; SettingChar(char x = '\0') : value(x) {} operator char() const { return value; } SettingChar & operator= (char x) { set(x); return *this; } String toString() const; void set(char x); void set(const String & x); void set(const Field & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; struct SettingDateTimeInputFormat { using Value = FormatSettings::DateTimeInputFormat; Value value; bool changed = false; SettingDateTimeInputFormat(Value x) : value(x) {} operator Value() const { return value; } SettingDateTimeInputFormat & operator= (Value x) { set(x); return *this; } static Value getValue(const String & s); String toString() const; void set(Value x); void set(const Field & x); void set(const String & x); void set(ReadBuffer & buf); void write(WriteBuffer & buf) const; }; class SettingLogsLevel { public: String value; bool changed = false; static const std::vector log_levels; SettingLogsLevel(const String & level); operator String() const { return value; } void set(const String & level); void set(const Field & level); void set(ReadBuffer & buf); String toString() const; void write(WriteBuffer & buf) const; }; }