reflect/protoreflect/value_union.go - protobuf - Git at Google

 // Copyright 2018 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package protoreflect

 import (
 	"fmt"
 	"math"
 	"reflect"
 )

 // Value is a union where only one Go type may be set at a time.
 // The Value is used to represent all possible values a field may take.
 // The following shows which Go type is used to represent each proto Kind:
 //
 //	╔════════════╤═════════════════════════════════════╗
 //	║ Go type    │ Protobuf kind                       ║
 //	╠════════════╪═════════════════════════════════════╣
 //	║ bool       │ BoolKind                            ║
 //	║ int32      │ Int32Kind, Sint32Kind, Sfixed32Kind ║
 //	║ int64      │ Int64Kind, Sint64Kind, Sfixed64Kind ║
 //	║ uint32     │ Uint32Kind, Fixed32Kind             ║
 //	║ uint64     │ Uint64Kind, Fixed64Kind             ║
 //	║ float32    │ FloatKind                           ║
 //	║ float64    │ DoubleKind                          ║
 //	║ string     │ StringKind                          ║
 //	║ []byte     │ BytesKind                           ║
 //	║ EnumNumber │ EnumKind                            ║
 //	║ Message    │ MessageKind, GroupKind              ║
 //	╚════════════╧═════════════════════════════════════╝
 //
 // Multiple protobuf Kinds may be represented by a single Go type if the type
 // can losslessly represent the information for the proto kind. For example,
 // Int64Kind, Sint64Kind, and Sfixed64Kind are all represented by int64,
 // but use different integer encoding methods.
 //
 // The List or Map types are used if the field cardinality is repeated.
 // A field is a List if FieldDescriptor.IsList reports true.
 // A field is a Map if FieldDescriptor.IsMap reports true.
 //
 // Converting to/from a Value and a concrete Go value panics on type mismatch.
 // For example, ValueOf("hello").Int() panics because this attempts to
 // retrieve an int64 from a string.
 type Value value

 // The protoreflect API uses a custom Value union type instead of interface{}
 // to keep the future open for performance optimizations. Using an interface{}
 // always incurs an allocation for primitives (e.g., int64) since it needs to
 // be boxed on the heap (as interfaces can only contain pointers natively).
 // Instead, we represent the Value union as a flat struct that internally keeps
 // track of which type is set. Using unsafe, the Value union can be reduced
 // down to 24B, which is identical in size to a slice.
 //
 // The latest compiler (Go1.11) currently suffers from some limitations:
 //	• With inlining, the compiler should be able to statically prove that
 //	only one of these switch cases are taken and inline one specific case.
 //	See https://golang.org/issue/22310.

 // ValueOf returns a Value initialized with the concrete value stored in v.
 // This panics if the type does not match one of the allowed types in the
 // Value union.
 func ValueOf(v interface{}) Value {
 	switch v := v.(type) {
 	case nil:
 		return Value{}
 	case bool:
 		return ValueOfBool(v)
 	case int32:
 		return ValueOfInt32(v)
 	case int64:
 		return ValueOfInt64(v)
 	case uint32:
 		return ValueOfUint32(v)
 	case uint64:
 		return ValueOfUint64(v)
 	case float32:
 		return ValueOfFloat32(v)
 	case float64:
 		return ValueOfFloat64(v)
 	case string:
 		return ValueOfString(v)
 	case []byte:
 		return ValueOfBytes(v)
 	case EnumNumber:
 		return ValueOfEnum(v)
 	case Message, List, Map:
 		return valueOfIface(v)
 	default:
 		panic(fmt.Sprintf("invalid type: %v", reflect.TypeOf(v)))
 	}
 }

 // ValueOfBool returns a new boolean value.
 func ValueOfBool(v bool) Value {
 	if v {
 		return Value{typ: boolType, num: 1}
 	} else {
 		return Value{typ: boolType, num: 0}
 	}
 }

 // ValueOfInt32 returns a new int32 value.
 func ValueOfInt32(v int32) Value {
 	return Value{typ: int32Type, num: uint64(v)}
 }

 // ValueOfInt64 returns a new int64 value.
 func ValueOfInt64(v int64) Value {
 	return Value{typ: int64Type, num: uint64(v)}
 }

 // ValueOfUint32 returns a new uint32 value.
 func ValueOfUint32(v uint32) Value {
 	return Value{typ: uint32Type, num: uint64(v)}
 }

 // ValueOfUint64 returns a new uint64 value.
 func ValueOfUint64(v uint64) Value {
 	return Value{typ: uint64Type, num: v}
 }

 // ValueOfFloat32 returns a new float32 value.
 func ValueOfFloat32(v float32) Value {
 	return Value{typ: float32Type, num: uint64(math.Float64bits(float64(v)))}
 }

 // ValueOfFloat64 returns a new float64 value.
 func ValueOfFloat64(v float64) Value {
 	return Value{typ: float64Type, num: uint64(math.Float64bits(float64(v)))}
 }

 // ValueOfString returns a new string value.
 func ValueOfString(v string) Value {
 	return valueOfString(v)
 }

 // ValueOfBytes returns a new bytes value.
 func ValueOfBytes(v []byte) Value {
 	return valueOfBytes(v[:len(v):len(v)])
 }

 // ValueOfEnum returns a new enum value.
 func ValueOfEnum(v EnumNumber) Value {
 	return Value{typ: enumType, num: uint64(v)}
 }

 // ValueOfMessage returns a new Message value.
 func ValueOfMessage(v Message) Value {
 	return valueOfIface(v)
 }

 // ValueOfList returns a new List value.
 func ValueOfList(v List) Value {
 	return valueOfIface(v)
 }

 // ValueOfMap returns a new Map value.
 func ValueOfMap(v Map) Value {
 	return valueOfIface(v)
 }

 // IsValid reports whether v is populated with a value.
 func (v Value) IsValid() bool {
 	return v.typ != nilType
 }

 // Interface returns v as an interface{}.
 //
 // Invariant: v == ValueOf(v).Interface()
 func (v Value) Interface() interface{} {
 	switch v.typ {
 	case nilType:
 		return nil
 	case boolType:
 		return v.Bool()
 	case int32Type:
 		return int32(v.Int())
 	case int64Type:
 		return int64(v.Int())
 	case uint32Type:
 		return uint32(v.Uint())
 	case uint64Type:
 		return uint64(v.Uint())
 	case float32Type:
 		return float32(v.Float())
 	case float64Type:
 		return float64(v.Float())
 	case stringType:
 		return v.String()
 	case bytesType:
 		return v.Bytes()
 	case enumType:
 		return v.Enum()
 	default:
 		return v.getIface()
 	}
 }

 // Bool returns v as a bool and panics if the type is not a bool.
 func (v Value) Bool() bool {
 	switch v.typ {
 	case boolType:
 		return v.num > 0
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // Int returns v as a int64 and panics if the type is not a int32 or int64.
 func (v Value) Int() int64 {
 	switch v.typ {
 	case int32Type, int64Type:
 		return int64(v.num)
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // Uint returns v as a uint64 and panics if the type is not a uint32 or uint64.
 func (v Value) Uint() uint64 {
 	switch v.typ {
 	case uint32Type, uint64Type:
 		return uint64(v.num)
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // Float returns v as a float64 and panics if the type is not a float32 or float64.
 func (v Value) Float() float64 {
 	switch v.typ {
 	case float32Type, float64Type:
 		return math.Float64frombits(uint64(v.num))
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // String returns v as a string. Since this method implements fmt.Stringer,
 // this returns the formatted string value for any non-string type.
 func (v Value) String() string {
 	switch v.typ {
 	case stringType:
 		return v.getString()
 	default:
 		return fmt.Sprint(v.Interface())
 	}
 }

 // Bytes returns v as a []byte and panics if the type is not a []byte.
 func (v Value) Bytes() []byte {
 	switch v.typ {
 	case bytesType:
 		return v.getBytes()
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // Enum returns v as a EnumNumber and panics if the type is not a EnumNumber.
 func (v Value) Enum() EnumNumber {
 	switch v.typ {
 	case enumType:
 		return EnumNumber(v.num)
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // Message returns v as a Message and panics if the type is not a Message.
 func (v Value) Message() Message {
 	switch v := v.getIface().(type) {
 	case Message:
 		return v
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // List returns v as a List and panics if the type is not a List.
 func (v Value) List() List {
 	switch v := v.getIface().(type) {
 	case List:
 		return v
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // Map returns v as a Map and panics if the type is not a Map.
 func (v Value) Map() Map {
 	switch v := v.getIface().(type) {
 	case Map:
 		return v
 	default:
 		panic("proto: value type mismatch")
 	}
 }

 // MapKey returns v as a MapKey and panics for invalid MapKey types.
 func (v Value) MapKey() MapKey {
 	switch v.typ {
 	case boolType, int32Type, int64Type, uint32Type, uint64Type, stringType:
 		return MapKey(v)
 	}
 	panic("proto: invalid map key type")
 }

 // MapKey is used to index maps, where the Go type of the MapKey must match
 // the specified key Kind (see MessageDescriptor.IsMapEntry).
 // The following shows what Go type is used to represent each proto Kind:
 //
 //	╔═════════╤═════════════════════════════════════╗
 //	║ Go type │ Protobuf kind                       ║
 //	╠═════════╪═════════════════════════════════════╣
 //	║ bool    │ BoolKind                            ║
 //	║ int32   │ Int32Kind, Sint32Kind, Sfixed32Kind ║
 //	║ int64   │ Int64Kind, Sint64Kind, Sfixed64Kind ║
 //	║ uint32  │ Uint32Kind, Fixed32Kind             ║
 //	║ uint64  │ Uint64Kind, Fixed64Kind             ║
 //	║ string  │ StringKind                          ║
 //	╚═════════╧═════════════════════════════════════╝
 //
 // A MapKey is constructed and accessed through a Value:
 //	k := ValueOf("hash").MapKey() // convert string to MapKey
 //	s := k.String()               // convert MapKey to string
 //
 // The MapKey is a strict subset of valid types used in Value;
 // converting a Value to a MapKey with an invalid type panics.
 type MapKey value

 // IsValid reports whether k is populated with a value.
 func (k MapKey) IsValid() bool {
 	return Value(k).IsValid()
 }

 // Interface returns k as an interface{}.
 func (k MapKey) Interface() interface{} {
 	return Value(k).Interface()
 }

 // Bool returns k as a bool and panics if the type is not a bool.
 func (k MapKey) Bool() bool {
 	return Value(k).Bool()
 }

 // Int returns k as a int64 and panics if the type is not a int32 or int64.
 func (k MapKey) Int() int64 {
 	return Value(k).Int()
 }

 // Uint returns k as a uint64 and panics if the type is not a uint32 or uint64.
 func (k MapKey) Uint() uint64 {
 	return Value(k).Uint()
 }

 // String returns k as a string. Since this method implements fmt.Stringer,
 // this returns the formatted string value for any non-string type.
 func (k MapKey) String() string {
 	return Value(k).String()
 }

 // Value returns k as a Value.
 func (k MapKey) Value() Value {
 	return Value(k)
 }
	// Copyright 2018 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package protoreflect

	import (
	"fmt"
	"math"
	"reflect"
	)

	// Value is a union where only one Go type may be set at a time.
	// The Value is used to represent all possible values a field may take.
	// The following shows which Go type is used to represent each proto Kind:
	//
	// ╔════════════╤═════════════════════════════════════╗
	// ║ Go type │ Protobuf kind ║
	// ╠════════════╪═════════════════════════════════════╣
	// ║ bool │ BoolKind ║
	// ║ int32 │ Int32Kind, Sint32Kind, Sfixed32Kind ║
	// ║ int64 │ Int64Kind, Sint64Kind, Sfixed64Kind ║
	// ║ uint32 │ Uint32Kind, Fixed32Kind ║
	// ║ uint64 │ Uint64Kind, Fixed64Kind ║
	// ║ float32 │ FloatKind ║
	// ║ float64 │ DoubleKind ║
	// ║ string │ StringKind ║
	// ║ []byte │ BytesKind ║
	// ║ EnumNumber │ EnumKind ║
	// ║ Message │ MessageKind, GroupKind ║
	// ╚════════════╧═════════════════════════════════════╝
	//
	// Multiple protobuf Kinds may be represented by a single Go type if the type
	// can losslessly represent the information for the proto kind. For example,
	// Int64Kind, Sint64Kind, and Sfixed64Kind are all represented by int64,
	// but use different integer encoding methods.
	//
	// The List or Map types are used if the field cardinality is repeated.
	// A field is a List if FieldDescriptor.IsList reports true.
	// A field is a Map if FieldDescriptor.IsMap reports true.
	//
	// Converting to/from a Value and a concrete Go value panics on type mismatch.
	// For example, ValueOf("hello").Int() panics because this attempts to
	// retrieve an int64 from a string.
	type Value value

	// The protoreflect API uses a custom Value union type instead of interface{}
	// to keep the future open for performance optimizations. Using an interface{}
	// always incurs an allocation for primitives (e.g., int64) since it needs to
	// be boxed on the heap (as interfaces can only contain pointers natively).
	// Instead, we represent the Value union as a flat struct that internally keeps
	// track of which type is set. Using unsafe, the Value union can be reduced
	// down to 24B, which is identical in size to a slice.
	//
	// The latest compiler (Go1.11) currently suffers from some limitations:
	// • With inlining, the compiler should be able to statically prove that
	// only one of these switch cases are taken and inline one specific case.
	// See https://golang.org/issue/22310.

	// ValueOf returns a Value initialized with the concrete value stored in v.
	// This panics if the type does not match one of the allowed types in the
	// Value union.
	func ValueOf(v interface{}) Value {
	switch v := v.(type) {
	case nil:
	return Value{}
	case bool:
	return ValueOfBool(v)
	case int32:
	return ValueOfInt32(v)
	case int64:
	return ValueOfInt64(v)
	case uint32:
	return ValueOfUint32(v)
	case uint64:
	return ValueOfUint64(v)
	case float32:
	return ValueOfFloat32(v)
	case float64:
	return ValueOfFloat64(v)
	case string:
	return ValueOfString(v)
	case []byte:
	return ValueOfBytes(v)
	case EnumNumber:
	return ValueOfEnum(v)
	case Message, List, Map:
	return valueOfIface(v)
	default:
	panic(fmt.Sprintf("invalid type: %v", reflect.TypeOf(v)))
	}
	}

	// ValueOfBool returns a new boolean value.
	func ValueOfBool(v bool) Value {
	if v {
	return Value{typ: boolType, num: 1}
	} else {
	return Value{typ: boolType, num: 0}
	}
	}

	// ValueOfInt32 returns a new int32 value.
	func ValueOfInt32(v int32) Value {
	return Value{typ: int32Type, num: uint64(v)}
	}

	// ValueOfInt64 returns a new int64 value.
	func ValueOfInt64(v int64) Value {
	return Value{typ: int64Type, num: uint64(v)}
	}

	// ValueOfUint32 returns a new uint32 value.
	func ValueOfUint32(v uint32) Value {
	return Value{typ: uint32Type, num: uint64(v)}
	}

	// ValueOfUint64 returns a new uint64 value.
	func ValueOfUint64(v uint64) Value {
	return Value{typ: uint64Type, num: v}
	}

	// ValueOfFloat32 returns a new float32 value.
	func ValueOfFloat32(v float32) Value {
	return Value{typ: float32Type, num: uint64(math.Float64bits(float64(v)))}
	}

	// ValueOfFloat64 returns a new float64 value.
	func ValueOfFloat64(v float64) Value {
	return Value{typ: float64Type, num: uint64(math.Float64bits(float64(v)))}
	}

	// ValueOfString returns a new string value.
	func ValueOfString(v string) Value {
	return valueOfString(v)
	}

	// ValueOfBytes returns a new bytes value.
	func ValueOfBytes(v []byte) Value {
	return valueOfBytes(v[:len(v):len(v)])
	}

	// ValueOfEnum returns a new enum value.
	func ValueOfEnum(v EnumNumber) Value {
	return Value{typ: enumType, num: uint64(v)}
	}

	// ValueOfMessage returns a new Message value.
	func ValueOfMessage(v Message) Value {
	return valueOfIface(v)
	}

	// ValueOfList returns a new List value.
	func ValueOfList(v List) Value {
	return valueOfIface(v)
	}

	// ValueOfMap returns a new Map value.
	func ValueOfMap(v Map) Value {
	return valueOfIface(v)
	}

	// IsValid reports whether v is populated with a value.
	func (v Value) IsValid() bool {
	return v.typ != nilType
	}

	// Interface returns v as an interface{}.
	//
	// Invariant: v == ValueOf(v).Interface()
	func (v Value) Interface() interface{} {
	switch v.typ {
	case nilType:
	return nil
	case boolType:
	return v.Bool()
	case int32Type:
	return int32(v.Int())
	case int64Type:
	return int64(v.Int())
	case uint32Type:
	return uint32(v.Uint())
	case uint64Type:
	return uint64(v.Uint())
	case float32Type:
	return float32(v.Float())
	case float64Type:
	return float64(v.Float())
	case stringType:
	return v.String()
	case bytesType:
	return v.Bytes()
	case enumType:
	return v.Enum()
	default:
	return v.getIface()
	}
	}

	// Bool returns v as a bool and panics if the type is not a bool.
	func (v Value) Bool() bool {
	switch v.typ {
	case boolType:
	return v.num > 0
	default:
	panic("proto: value type mismatch")
	}
	}

	// Int returns v as a int64 and panics if the type is not a int32 or int64.
	func (v Value) Int() int64 {
	switch v.typ {
	case int32Type, int64Type:
	return int64(v.num)
	default:
	panic("proto: value type mismatch")
	}
	}

	// Uint returns v as a uint64 and panics if the type is not a uint32 or uint64.
	func (v Value) Uint() uint64 {
	switch v.typ {
	case uint32Type, uint64Type:
	return uint64(v.num)
	default:
	panic("proto: value type mismatch")
	}
	}

	// Float returns v as a float64 and panics if the type is not a float32 or float64.
	func (v Value) Float() float64 {
	switch v.typ {
	case float32Type, float64Type:
	return math.Float64frombits(uint64(v.num))
	default:
	panic("proto: value type mismatch")
	}
	}

	// String returns v as a string. Since this method implements fmt.Stringer,
	// this returns the formatted string value for any non-string type.
	func (v Value) String() string {
	switch v.typ {
	case stringType:
	return v.getString()
	default:
	return fmt.Sprint(v.Interface())
	}
	}

	// Bytes returns v as a []byte and panics if the type is not a []byte.
	func (v Value) Bytes() []byte {
	switch v.typ {
	case bytesType:
	return v.getBytes()
	default:
	panic("proto: value type mismatch")
	}
	}

	// Enum returns v as a EnumNumber and panics if the type is not a EnumNumber.
	func (v Value) Enum() EnumNumber {
	switch v.typ {
	case enumType:
	return EnumNumber(v.num)
	default:
	panic("proto: value type mismatch")
	}
	}

	// Message returns v as a Message and panics if the type is not a Message.
	func (v Value) Message() Message {
	switch v := v.getIface().(type) {
	case Message:
	return v
	default:
	panic("proto: value type mismatch")
	}
	}

	// List returns v as a List and panics if the type is not a List.
	func (v Value) List() List {
	switch v := v.getIface().(type) {
	case List:
	return v
	default:
	panic("proto: value type mismatch")
	}
	}

	// Map returns v as a Map and panics if the type is not a Map.
	func (v Value) Map() Map {
	switch v := v.getIface().(type) {
	case Map:
	return v
	default:
	panic("proto: value type mismatch")
	}
	}

	// MapKey returns v as a MapKey and panics for invalid MapKey types.
	func (v Value) MapKey() MapKey {
	switch v.typ {
	case boolType, int32Type, int64Type, uint32Type, uint64Type, stringType:
	return MapKey(v)
	}
	panic("proto: invalid map key type")
	}

	// MapKey is used to index maps, where the Go type of the MapKey must match
	// the specified key Kind (see MessageDescriptor.IsMapEntry).
	// The following shows what Go type is used to represent each proto Kind:
	//
	// ╔═════════╤═════════════════════════════════════╗
	// ║ Go type │ Protobuf kind ║
	// ╠═════════╪═════════════════════════════════════╣
	// ║ bool │ BoolKind ║
	// ║ int32 │ Int32Kind, Sint32Kind, Sfixed32Kind ║
	// ║ int64 │ Int64Kind, Sint64Kind, Sfixed64Kind ║
	// ║ uint32 │ Uint32Kind, Fixed32Kind ║
	// ║ uint64 │ Uint64Kind, Fixed64Kind ║
	// ║ string │ StringKind ║
	// ╚═════════╧═════════════════════════════════════╝
	//
	// A MapKey is constructed and accessed through a Value:
	// k := ValueOf("hash").MapKey() // convert string to MapKey
	// s := k.String() // convert MapKey to string
	//
	// The MapKey is a strict subset of valid types used in Value;
	// converting a Value to a MapKey with an invalid type panics.
	type MapKey value

	// IsValid reports whether k is populated with a value.
	func (k MapKey) IsValid() bool {
	return Value(k).IsValid()
	}

	// Interface returns k as an interface{}.
	func (k MapKey) Interface() interface{} {
	return Value(k).Interface()
	}

	// Bool returns k as a bool and panics if the type is not a bool.
	func (k MapKey) Bool() bool {
	return Value(k).Bool()
	}

	// Int returns k as a int64 and panics if the type is not a int32 or int64.
	func (k MapKey) Int() int64 {
	return Value(k).Int()
	}

	// Uint returns k as a uint64 and panics if the type is not a uint32 or uint64.
	func (k MapKey) Uint() uint64 {
	return Value(k).Uint()
	}

	// String returns k as a string. Since this method implements fmt.Stringer,
	// this returns the formatted string value for any non-string type.
	func (k MapKey) String() string {
	return Value(k).String()
	}

	// Value returns k as a Value.
	func (k MapKey) Value() Value {
	return Value(k)
	}