add some basic sql types

copied some code from vitness
5 years ago · e26670c67a
4 changed files with 613 additions and 0 deletions
--- a/weed/query/sqltypes/const.go
+++ b/weed/query/sqltypes/const.go
@ -0,0 +1,124 @@
 package sqltypes
 // copied from vitness
 // Flag allows us to qualify types by their common properties.
 type Flag int32
 const (
 	Flag_NONE       Flag = 0
 	Flag_ISINTEGRAL Flag = 256
 	Flag_ISUNSIGNED Flag = 512
 	Flag_ISFLOAT    Flag = 1024
 	Flag_ISQUOTED   Flag = 2048
 	Flag_ISTEXT     Flag = 4096
 	Flag_ISBINARY   Flag = 8192
 )
 var Flag_name = map[int32]string{
 	0:    "NONE",
 	256:  "ISINTEGRAL",
 	512:  "ISUNSIGNED",
 	1024: "ISFLOAT",
 	2048: "ISQUOTED",
 	4096: "ISTEXT",
 	8192: "ISBINARY",
 }
 var Flag_value = map[string]int32{
 	"NONE":       0,
 	"ISINTEGRAL": 256,
 	"ISUNSIGNED": 512,
 	"ISFLOAT":    1024,
 	"ISQUOTED":   2048,
 	"ISTEXT":     4096,
 	"ISBINARY":   8192,
 }
 // Type defines the various supported data types in bind vars
 // and query results.
 type Type int32
 const (
 	// NULL_TYPE specifies a NULL type.
 	Type_NULL_TYPE Type = 0
 	// INT8 specifies a TINYINT type.
 	// Properties: 1, IsNumber.
 	Type_INT8 Type = 257
 	// UINT8 specifies a TINYINT UNSIGNED type.
 	// Properties: 2, IsNumber, IsUnsigned.
 	Type_UINT8 Type = 770
 	// INT16 specifies a SMALLINT type.
 	// Properties: 3, IsNumber.
 	Type_INT16 Type = 259
 	// UINT16 specifies a SMALLINT UNSIGNED type.
 	// Properties: 4, IsNumber, IsUnsigned.
 	Type_UINT16 Type = 772
 	// INT24 specifies a MEDIUMINT type.
 	// Properties: 5, IsNumber.
 	Type_INT32 Type = 263
 	// UINT32 specifies a INTEGER UNSIGNED type.
 	// Properties: 8, IsNumber, IsUnsigned.
 	Type_UINT32 Type = 776
 	// INT64 specifies a BIGINT type.
 	// Properties: 9, IsNumber.
 	Type_INT64 Type = 265
 	// UINT64 specifies a BIGINT UNSIGNED type.
 	// Properties: 10, IsNumber, IsUnsigned.
 	Type_UINT64 Type = 778
 	// FLOAT32 specifies a FLOAT type.
 	// Properties: 11, IsFloat.
 	Type_FLOAT32 Type = 1035
 	// FLOAT64 specifies a DOUBLE or REAL type.
 	// Properties: 12, IsFloat.
 	Type_FLOAT64 Type = 1036
 	// TIMESTAMP specifies a TIMESTAMP type.
 	// Properties: 13, IsQuoted.
 	Type_TIMESTAMP Type = 2061
 	// DATE specifies a DATE type.
 	// Properties: 14, IsQuoted.
 	Type_DATE Type = 2062
 	// TIME specifies a TIME type.
 	// Properties: 15, IsQuoted.
 	Type_TIME Type = 2063
 	// DATETIME specifies a DATETIME type.
 	// Properties: 16, IsQuoted.
 	Type_DATETIME Type = 2064
 	// YEAR specifies a YEAR type.
 	// Properties: 17, IsNumber, IsUnsigned.
 	Type_YEAR Type = 785
 	// DECIMAL specifies a DECIMAL or NUMERIC type.
 	// Properties: 18, None.
 	Type_DECIMAL Type = 18
 	// TEXT specifies a TEXT type.
 	// Properties: 19, IsQuoted, IsText.
 	Type_TEXT Type = 6163
 	// BLOB specifies a BLOB type.
 	// Properties: 20, IsQuoted, IsBinary.
 	Type_BLOB Type = 10260
 	// VARCHAR specifies a VARCHAR type.
 	// Properties: 21, IsQuoted, IsText.
 	Type_VARCHAR Type = 6165
 	// VARBINARY specifies a VARBINARY type.
 	// Properties: 22, IsQuoted, IsBinary.
 	Type_VARBINARY Type = 10262
 	// CHAR specifies a CHAR type.
 	// Properties: 23, IsQuoted, IsText.
 	Type_CHAR Type = 6167
 	// BINARY specifies a BINARY type.
 	// Properties: 24, IsQuoted, IsBinary.
 	Type_BINARY Type = 10264
 	// BIT specifies a BIT type.
 	// Properties: 25, IsQuoted.
 	Type_BIT Type = 2073
 	// JSON specifies a JSON type.
 	// Properties: 30, IsQuoted.
 	Type_JSON Type = 2078
 )
 // BindVariable represents a single bind variable in a Query.
 type BindVariable struct {
 	Type  Type   `protobuf:"varint,1,opt,name=type,enum=query.Type" json:"type,omitempty"`
 	Value []byte `protobuf:"bytes,2,opt,name=value,proto3" json:"value,omitempty"`
 	// values are set if type is TUPLE.
 	Values []*Value `protobuf:"bytes,3,rep,name=values" json:"values,omitempty"`
 }
--- a/weed/query/sqltypes/type.go
+++ b/weed/query/sqltypes/type.go
@ -0,0 +1,102 @@
 package sqltypes
 // These bit flags can be used to query on the
 // common properties of types.
 const (
 	flagIsIntegral = int(Flag_ISINTEGRAL)
 	flagIsUnsigned = int(Flag_ISUNSIGNED)
 	flagIsFloat    = int(Flag_ISFLOAT)
 	flagIsQuoted   = int(Flag_ISQUOTED)
 	flagIsText     = int(Flag_ISTEXT)
 	flagIsBinary   = int(Flag_ISBINARY)
 )
 // IsIntegral returns true if Type is an integral
 // (signed/unsigned) that can be represented using
 // up to 64 binary bits.
 // If you have a Value object, use its member function.
 func IsIntegral(t Type) bool {
 	return int(t)&flagIsIntegral == flagIsIntegral
 }
 // IsSigned returns true if Type is a signed integral.
 // If you have a Value object, use its member function.
 func IsSigned(t Type) bool {
 	return int(t)&(flagIsIntegral|flagIsUnsigned) == flagIsIntegral
 }
 // IsUnsigned returns true if Type is an unsigned integral.
 // Caution: this is not the same as !IsSigned.
 // If you have a Value object, use its member function.
 func IsUnsigned(t Type) bool {
 	return int(t)&(flagIsIntegral|flagIsUnsigned) == flagIsIntegral|flagIsUnsigned
 }
 // IsFloat returns true is Type is a floating point.
 // If you have a Value object, use its member function.
 func IsFloat(t Type) bool {
 	return int(t)&flagIsFloat == flagIsFloat
 }
 // IsQuoted returns true if Type is a quoted text or binary.
 // If you have a Value object, use its member function.
 func IsQuoted(t Type) bool {
 	return (int(t)&flagIsQuoted == flagIsQuoted) && t != Bit
 }
 // IsText returns true if Type is a text.
 // If you have a Value object, use its member function.
 func IsText(t Type) bool {
 	return int(t)&flagIsText == flagIsText
 }
 // IsBinary returns true if Type is a binary.
 // If you have a Value object, use its member function.
 func IsBinary(t Type) bool {
 	return int(t)&flagIsBinary == flagIsBinary
 }
 // isNumber returns true if the type is any type of number.
 func isNumber(t Type) bool {
 	return IsIntegral(t) || IsFloat(t) || t == Decimal
 }
 // IsTemporal returns true if Value is time type.
 func IsTemporal(t Type) bool {
 	switch t {
 	case Timestamp, Date, Time, Datetime:
 		return true
 	}
 	return false
 }
 // Vitess data types. These are idiomatically
 // named synonyms for the Type values.
 const (
 	Null       = Type_NULL_TYPE
 	Int8       = Type_INT8
 	Uint8      = Type_UINT8
 	Int16      = Type_INT16
 	Uint16     = Type_UINT16
 	Int32      = Type_INT32
 	Uint32     = Type_UINT32
 	Int64      = Type_INT64
 	Uint64     = Type_UINT64
 	Float32    = Type_FLOAT32
 	Float64    = Type_FLOAT64
 	Timestamp  = Type_TIMESTAMP
 	Date       = Type_DATE
 	Time       = Type_TIME
 	Datetime   = Type_DATETIME
 	Year       = Type_YEAR
 	Decimal    = Type_DECIMAL
 	Text       = Type_TEXT
 	Blob       = Type_BLOB
 	VarChar    = Type_VARCHAR
 	VarBinary  = Type_VARBINARY
 	Char       = Type_CHAR
 	Binary     = Type_BINARY
 	Bit        = Type_BIT
 	TypeJSON   = Type_JSON
 )
--- a/weed/query/sqltypes/unsafe.go
+++ b/weed/query/sqltypes/unsafe.go
@ -0,0 +1,30 @@
 package sqltypes
 import (
 	"reflect"
 	"unsafe"
 )
 // BytesToString casts slice to string without copy
 func BytesToString(b []byte) (s string) {
 	if len(b) == 0 {
 		return ""
 	}
 	bh := (*reflect.SliceHeader)(unsafe.Pointer(&b))
 	sh := reflect.StringHeader{Data: bh.Data, Len: bh.Len}
 	return *(*string)(unsafe.Pointer(&sh))
 }
 // StringToBytes casts string to slice without copy
 func StringToBytes(s string) []byte {
 	if len(s) == 0 {
 		return []byte{}
 	}
 	sh := (*reflect.StringHeader)(unsafe.Pointer(&s))
 	bh := reflect.SliceHeader{Data: sh.Data, Len: sh.Len, Cap: sh.Len}
 	return *(*[]byte)(unsafe.Pointer(&bh))
 }
--- a/weed/query/sqltypes/value.go
+++ b/weed/query/sqltypes/value.go
@ -0,0 +1,357 @@
 package sqltypes
 import (
 	"fmt"
 	"strconv"
 	"time"
 )
 var (
 	// NULL represents the NULL value.
 	NULL = Value{}
 	// DontEscape tells you if a character should not be escaped.
 	DontEscape = byte(255)
 	nullstr    = []byte("null")
 )
 type Value struct {
 	typ Type
 	val []byte
 }
 // NewValue builds a Value using typ and val. If the value and typ
 // don't match, it returns an error.
 func NewValue(typ Type, val []byte) (v Value, err error) {
 	switch {
 	case IsSigned(typ):
 		if _, err := strconv.ParseInt(string(val), 0, 64); err != nil {
 			return NULL, err
 		}
 		return MakeTrusted(typ, val), nil
 	case IsUnsigned(typ):
 		if _, err := strconv.ParseUint(string(val), 0, 64); err != nil {
 			return NULL, err
 		}
 		return MakeTrusted(typ, val), nil
 	case IsFloat(typ) || typ == Decimal:
 		if _, err := strconv.ParseFloat(string(val), 64); err != nil {
 			return NULL, err
 		}
 		return MakeTrusted(typ, val), nil
 	case IsQuoted(typ) || typ == Bit || typ == Null:
 		return MakeTrusted(typ, val), nil
 	}
 	// All other types are unsafe or invalid.
 	return NULL, fmt.Errorf("invalid type specified for MakeValue: %v", typ)
 }
 // MakeTrusted makes a new Value based on the type.
 // This function should only be used if you know the value
 // and type conform to the rules. Every place this function is
 // called, a comment is needed that explains why it's justified.
 // Exceptions: The current package and mysql package do not need
 // comments. Other packages can also use the function to create
 // VarBinary or VarChar values.
 func MakeTrusted(typ Type, val []byte) Value {
 	if typ == Null {
 		return NULL
 	}
 	return Value{typ: typ, val: val}
 }
 // NewInt64 builds an Int64 Value.
 func NewInt64(v int64) Value {
 	return MakeTrusted(Int64, strconv.AppendInt(nil, v, 10))
 }
 // NewInt32 builds an Int64 Value.
 func NewInt32(v int32) Value {
 	return MakeTrusted(Int32, strconv.AppendInt(nil, int64(v), 10))
 }
 // NewUint64 builds an Uint64 Value.
 func NewUint64(v uint64) Value {
 	return MakeTrusted(Uint64, strconv.AppendUint(nil, v, 10))
 }
 // NewFloat32 builds an Float64 Value.
 func NewFloat32(v float32) Value {
 	return MakeTrusted(Float32, strconv.AppendFloat(nil, float64(v), 'f', -1, 64))
 }
 // NewFloat64 builds an Float64 Value.
 func NewFloat64(v float64) Value {
 	return MakeTrusted(Float64, strconv.AppendFloat(nil, v, 'g', -1, 64))
 }
 // NewVarChar builds a VarChar Value.
 func NewVarChar(v string) Value {
 	return MakeTrusted(VarChar, []byte(v))
 }
 // NewVarBinary builds a VarBinary Value.
 // The input is a string because it's the most common use case.
 func NewVarBinary(v string) Value {
 	return MakeTrusted(VarBinary, []byte(v))
 }
 // NewIntegral builds an integral type from a string representation.
 // The type will be Int64 or Uint64. Int64 will be preferred where possible.
 func NewIntegral(val string) (n Value, err error) {
 	signed, err := strconv.ParseInt(val, 0, 64)
 	if err == nil {
 		return MakeTrusted(Int64, strconv.AppendInt(nil, signed, 10)), nil
 	}
 	unsigned, err := strconv.ParseUint(val, 0, 64)
 	if err != nil {
 		return Value{}, err
 	}
 	return MakeTrusted(Uint64, strconv.AppendUint(nil, unsigned, 10)), nil
 }
 // MakeString makes a VarBinary Value.
 func MakeString(val []byte) Value {
 	return MakeTrusted(VarBinary, val)
 }
 // BuildValue builds a value from any go type. sqltype.Value is
 // also allowed.
 func BuildValue(goval interface{}) (v Value, err error) {
 	// Look for the most common types first.
 	switch goval := goval.(type) {
 	case nil:
 		// no op
 	case []byte:
 		v = MakeTrusted(VarBinary, goval)
 	case int64:
 		v = MakeTrusted(Int64, strconv.AppendInt(nil, int64(goval), 10))
 	case uint64:
 		v = MakeTrusted(Uint64, strconv.AppendUint(nil, uint64(goval), 10))
 	case float64:
 		v = MakeTrusted(Float64, strconv.AppendFloat(nil, goval, 'f', -1, 64))
 	case int:
 		v = MakeTrusted(Int64, strconv.AppendInt(nil, int64(goval), 10))
 	case int8:
 		v = MakeTrusted(Int8, strconv.AppendInt(nil, int64(goval), 10))
 	case int16:
 		v = MakeTrusted(Int16, strconv.AppendInt(nil, int64(goval), 10))
 	case int32:
 		v = MakeTrusted(Int32, strconv.AppendInt(nil, int64(goval), 10))
 	case uint:
 		v = MakeTrusted(Uint64, strconv.AppendUint(nil, uint64(goval), 10))
 	case uint8:
 		v = MakeTrusted(Uint8, strconv.AppendUint(nil, uint64(goval), 10))
 	case uint16:
 		v = MakeTrusted(Uint16, strconv.AppendUint(nil, uint64(goval), 10))
 	case uint32:
 		v = MakeTrusted(Uint32, strconv.AppendUint(nil, uint64(goval), 10))
 	case float32:
 		v = MakeTrusted(Float32, strconv.AppendFloat(nil, float64(goval), 'f', -1, 64))
 	case string:
 		v = MakeTrusted(VarBinary, []byte(goval))
 	case time.Time:
 		v = MakeTrusted(Datetime, []byte(goval.Format("2006-01-02 15:04:05")))
 	case Value:
 		v = goval
 	case *BindVariable:
 		return ValueFromBytes(goval.Type, goval.Value)
 	default:
 		return v, fmt.Errorf("unexpected type %T: %v", goval, goval)
 	}
 	return v, nil
 }
 // BuildConverted is like BuildValue except that it tries to
 // convert a string or []byte to an integral if the target type
 // is an integral. We don't perform other implicit conversions
 // because they're unsafe.
 func BuildConverted(typ Type, goval interface{}) (v Value, err error) {
 	if IsIntegral(typ) {
 		switch goval := goval.(type) {
 		case []byte:
 			return ValueFromBytes(typ, goval)
 		case string:
 			return ValueFromBytes(typ, []byte(goval))
 		case Value:
 			if goval.IsQuoted() {
 				return ValueFromBytes(typ, goval.Raw())
 			}
 		}
 	}
 	return BuildValue(goval)
 }
 // ValueFromBytes builds a Value using typ and val. It ensures that val
 // matches the requested type. If type is an integral it's converted to
 // a canonical form. Otherwise, the original representation is preserved.
 func ValueFromBytes(typ Type, val []byte) (v Value, err error) {
 	switch {
 	case IsSigned(typ):
 		signed, err := strconv.ParseInt(string(val), 0, 64)
 		if err != nil {
 			return NULL, err
 		}
 		v = MakeTrusted(typ, strconv.AppendInt(nil, signed, 10))
 	case IsUnsigned(typ):
 		unsigned, err := strconv.ParseUint(string(val), 0, 64)
 		if err != nil {
 			return NULL, err
 		}
 		v = MakeTrusted(typ, strconv.AppendUint(nil, unsigned, 10))
 	case IsFloat(typ) || typ == Decimal:
 		_, err := strconv.ParseFloat(string(val), 64)
 		if err != nil {
 			return NULL, err
 		}
 		// After verification, we preserve the original representation.
 		fallthrough
 	default:
 		v = MakeTrusted(typ, val)
 	}
 	return v, nil
 }
 // BuildIntegral builds an integral type from a string representation.
 // The type will be Int64 or Uint64. Int64 will be preferred where possible.
 func BuildIntegral(val string) (n Value, err error) {
 	signed, err := strconv.ParseInt(val, 0, 64)
 	if err == nil {
 		return MakeTrusted(Int64, strconv.AppendInt(nil, signed, 10)), nil
 	}
 	unsigned, err := strconv.ParseUint(val, 0, 64)
 	if err != nil {
 		return Value{}, err
 	}
 	return MakeTrusted(Uint64, strconv.AppendUint(nil, unsigned, 10)), nil
 }
 // Type returns the type of Value.
 func (v Value) Type() Type {
 	return v.typ
 }
 // Raw returns the raw bytes. All types are currently implemented as []byte.
 // You should avoid using this function. If you do, you should treat the
 // bytes as read-only.
 func (v Value) Raw() []byte {
 	return v.val
 }
 // Len returns the length.
 func (v Value) Len() int {
 	return len(v.val)
 }
 // Values represents the array of Value.
 type Values []Value
 // Len implements the interface.
 func (vs Values) Len() int {
 	len := 0
 	for _, v := range vs {
 		len += v.Len()
 	}
 	return len
 }
 // String returns the raw value as a string.
 func (v Value) String() string {
 	return BytesToString(v.val)
 }
 // ToNative converts Value to a native go type.
 // This does not work for sqltypes.Tuple. The function
 // panics if there are inconsistencies.
 func (v Value) ToNative() interface{} {
 	var out interface{}
 	var err error
 	switch {
 	case v.typ == Null:
 		// no-op
 	case IsSigned(v.typ):
 		out, err = v.ParseInt64()
 	case IsUnsigned(v.typ):
 		out, err = v.ParseUint64()
 	case IsFloat(v.typ):
 		out, err = v.ParseFloat64()
 	default:
 		out = v.val
 	}
 	if err != nil {
 		panic(err)
 	}
 	return out
 }
 // ParseInt64 will parse a Value into an int64. It does
 // not check the type.
 func (v Value) ParseInt64() (val int64, err error) {
 	return strconv.ParseInt(v.String(), 10, 64)
 }
 // ParseUint64 will parse a Value into a uint64. It does
 // not check the type.
 func (v Value) ParseUint64() (val uint64, err error) {
 	return strconv.ParseUint(v.String(), 10, 64)
 }
 // ParseFloat64 will parse a Value into an float64. It does
 // not check the type.
 func (v Value) ParseFloat64() (val float64, err error) {
 	return strconv.ParseFloat(v.String(), 64)
 }
 // IsNull returns true if Value is null.
 func (v Value) IsNull() bool {
 	return v.typ == Null
 }
 // IsIntegral returns true if Value is an integral.
 func (v Value) IsIntegral() bool {
 	return IsIntegral(v.typ)
 }
 // IsSigned returns true if Value is a signed integral.
 func (v Value) IsSigned() bool {
 	return IsSigned(v.typ)
 }
 // IsUnsigned returns true if Value is an unsigned integral.
 func (v Value) IsUnsigned() bool {
 	return IsUnsigned(v.typ)
 }
 // IsFloat returns true if Value is a float.
 func (v Value) IsFloat() bool {
 	return IsFloat(v.typ)
 }
 // IsQuoted returns true if Value must be SQL-quoted.
 func (v Value) IsQuoted() bool {
 	return IsQuoted(v.typ)
 }
 // IsText returns true if Value is a collatable text.
 func (v Value) IsText() bool {
 	return IsText(v.typ)
 }
 // IsBinary returns true if Value is binary.
 func (v Value) IsBinary() bool {
 	return IsBinary(v.typ)
 }
 // IsTemporal returns true if Value is time type.
 func (v Value) IsTemporal() bool {
 	return IsTemporal(v.typ)
 }
 // ToString returns the value as MySQL would return it as string.
 // If the value is not convertible like in the case of Expression, it returns nil.
 func (v Value) ToString() string {
 	return BytesToString(v.val)
 }