vendor/github.com/jhump/protoreflect/dynamic/message_factory.go - voltha-openolt-adapter - Gitiles

 package dynamic

 import (
 	"reflect"
 	"sync"

 	"github.com/golang/protobuf/proto"

 	"github.com/jhump/protoreflect/desc"
 )

 // MessageFactory can be used to create new empty message objects. A default instance
 // (without extension registry or known-type registry specified) will always return
 // dynamic messages (e.g. type will be *dynamic.Message) except for "well-known" types.
 // The well-known types include primitive wrapper types and a handful of other special
 // types defined in standard protobuf definitions, like Any, Duration, and Timestamp.
 type MessageFactory struct {
 	er  *ExtensionRegistry
 	ktr *KnownTypeRegistry
 }

 // NewMessageFactoryWithExtensionRegistry creates a new message factory where any
 // dynamic messages produced will use the given extension registry to recognize and
 // parse extension fields.
 func NewMessageFactoryWithExtensionRegistry(er *ExtensionRegistry) *MessageFactory {
 	return NewMessageFactoryWithRegistries(er, nil)
 }

 // NewMessageFactoryWithKnownTypeRegistry creates a new message factory where the
 // known types, per the given registry, will be returned as normal protobuf messages
 // (e.g. generated structs, instead of dynamic messages).
 func NewMessageFactoryWithKnownTypeRegistry(ktr *KnownTypeRegistry) *MessageFactory {
 	return NewMessageFactoryWithRegistries(nil, ktr)
 }

 // NewMessageFactoryWithDefaults creates a new message factory where all "default" types
 // (those for which protoc-generated code is statically linked into the Go program) are
 // known types. If any dynamic messages are produced, they will recognize and parse all
 // "default" extension fields. This is the equivalent of:
 //   NewMessageFactoryWithRegistries(
 //       NewExtensionRegistryWithDefaults(),
 //       NewKnownTypeRegistryWithDefaults())
 func NewMessageFactoryWithDefaults() *MessageFactory {
 	return NewMessageFactoryWithRegistries(NewExtensionRegistryWithDefaults(), NewKnownTypeRegistryWithDefaults())
 }

 // NewMessageFactoryWithRegistries creates a new message factory with the given extension
 // and known type registries.
 func NewMessageFactoryWithRegistries(er *ExtensionRegistry, ktr *KnownTypeRegistry) *MessageFactory {
 	return &MessageFactory{
 		er:  er,
 		ktr: ktr,
 	}
 }

 // NewMessage creates a new empty message that corresponds to the given descriptor.
 // If the given descriptor describes a "known type" then that type is instantiated.
 // Otherwise, an empty dynamic message is returned.
 func (f *MessageFactory) NewMessage(md *desc.MessageDescriptor) proto.Message {
 	var ktr *KnownTypeRegistry
 	if f != nil {
 		ktr = f.ktr
 	}
 	if m := ktr.CreateIfKnown(md.GetFullyQualifiedName()); m != nil {
 		return m
 	}
 	return NewMessageWithMessageFactory(md, f)
 }

 // NewDynamicMessage creates a new empty dynamic message that corresponds to the given
 // descriptor. This is like f.NewMessage(md) except the known type registry is not
 // consulted so the return value is always a dynamic message.
 //
 // This is also like dynamic.NewMessage(md) except that the returned message will use
 // this factory when creating other messages, like during de-serialization of fields
 // that are themselves message types.
 func (f *MessageFactory) NewDynamicMessage(md *desc.MessageDescriptor) *Message {
 	return NewMessageWithMessageFactory(md, f)
 }

 // GetKnownTypeRegistry returns the known type registry that this factory uses to
 // instantiate known (e.g. generated) message types.
 func (f *MessageFactory) GetKnownTypeRegistry() *KnownTypeRegistry {
 	if f == nil {
 		return nil
 	}
 	return f.ktr
 }

 // GetExtensionRegistry returns the extension registry that this factory uses to
 // create dynamic messages. The registry is used by dynamic messages to recognize
 // and parse extension fields during de-serialization.
 func (f *MessageFactory) GetExtensionRegistry() *ExtensionRegistry {
 	if f == nil {
 		return nil
 	}
 	return f.er
 }

 type wkt interface {
 	XXX_WellKnownType() string
 }

 var typeOfWkt = reflect.TypeOf((*wkt)(nil)).Elem()

 // KnownTypeRegistry is a registry of known message types, as identified by their
 // fully-qualified name. A known message type is one for which a protoc-generated
 // struct exists, so a dynamic message is not necessary to represent it. A
 // MessageFactory uses a KnownTypeRegistry to decide whether to create a generated
 // struct or a dynamic message. The zero-value registry (including the behavior of
 // a nil pointer) only knows about the "well-known types" in protobuf. These
 // include only the wrapper types and a handful of other special types like Any,
 // Duration, and Timestamp.
 type KnownTypeRegistry struct {
 	excludeWkt     bool
 	includeDefault bool
 	mu             sync.RWMutex
 	types          map[string]reflect.Type
 }

 // NewKnownTypeRegistryWithDefaults creates a new registry that knows about all
 // "default" types (those for which protoc-generated code is statically linked
 // into the Go program).
 func NewKnownTypeRegistryWithDefaults() *KnownTypeRegistry {
 	return &KnownTypeRegistry{includeDefault: true}
 }

 // NewKnownTypeRegistryWithoutWellKnownTypes creates a new registry that does *not*
 // include the "well-known types" in protobuf. So even well-known types would be
 // represented by a dynamic message.
 func NewKnownTypeRegistryWithoutWellKnownTypes() *KnownTypeRegistry {
 	return &KnownTypeRegistry{excludeWkt: true}
 }

 // AddKnownType adds the types of the given messages as known types.
 func (r *KnownTypeRegistry) AddKnownType(kts ...proto.Message) {
 	r.mu.Lock()
 	defer r.mu.Unlock()
 	if r.types == nil {
 		r.types = map[string]reflect.Type{}
 	}
 	for _, kt := range kts {
 		r.types[proto.MessageName(kt)] = reflect.TypeOf(kt)
 	}
 }

 // CreateIfKnown will construct an instance of the given message if it is a known type.
 // If the given name is unknown, nil is returned.
 func (r *KnownTypeRegistry) CreateIfKnown(messageName string) proto.Message {
 	msgType := r.GetKnownType(messageName)
 	if msgType == nil {
 		return nil
 	}

 	if msgType.Kind() == reflect.Ptr {
 		return reflect.New(msgType.Elem()).Interface().(proto.Message)
 	} else {
 		return reflect.New(msgType).Elem().Interface().(proto.Message)
 	}
 }

 func isWellKnownType(t reflect.Type) bool {
 	if t.Implements(typeOfWkt) {
 		return true
 	}
 	if msg, ok := reflect.Zero(t).Interface().(proto.Message); ok {
 		name := proto.MessageName(msg)
 		_, ok := wellKnownTypeNames[name]
 		return ok
 	}
 	return false
 }

 // GetKnownType will return the reflect.Type for the given message name if it is
 // known. If it is not known, nil is returned.
 func (r *KnownTypeRegistry) GetKnownType(messageName string) reflect.Type {
 	var msgType reflect.Type
 	if r == nil {
 		// a nil registry behaves the same as zero value instance: only know of well-known types
 		t := proto.MessageType(messageName)
 		if t != nil && isWellKnownType(t) {
 			msgType = t
 		}
 	} else {
 		if r.includeDefault {
 			msgType = proto.MessageType(messageName)
 		} else if !r.excludeWkt {
 			t := proto.MessageType(messageName)
 			if t != nil && isWellKnownType(t) {
 				msgType = t
 			}
 		}
 		if msgType == nil {
 			r.mu.RLock()
 			msgType = r.types[messageName]
 			r.mu.RUnlock()
 		}
 	}

 	return msgType
 }
	package dynamic

	import (
	"reflect"
	"sync"

	"github.com/golang/protobuf/proto"

	"github.com/jhump/protoreflect/desc"
	)

	// MessageFactory can be used to create new empty message objects. A default instance
	// (without extension registry or known-type registry specified) will always return
	// dynamic messages (e.g. type will be *dynamic.Message) except for "well-known" types.
	// The well-known types include primitive wrapper types and a handful of other special
	// types defined in standard protobuf definitions, like Any, Duration, and Timestamp.
	type MessageFactory struct {
	er *ExtensionRegistry
	ktr *KnownTypeRegistry
	}

	// NewMessageFactoryWithExtensionRegistry creates a new message factory where any
	// dynamic messages produced will use the given extension registry to recognize and
	// parse extension fields.
	func NewMessageFactoryWithExtensionRegistry(er ExtensionRegistry) MessageFactory {
	return NewMessageFactoryWithRegistries(er, nil)
	}

	// NewMessageFactoryWithKnownTypeRegistry creates a new message factory where the
	// known types, per the given registry, will be returned as normal protobuf messages
	// (e.g. generated structs, instead of dynamic messages).
	func NewMessageFactoryWithKnownTypeRegistry(ktr KnownTypeRegistry) MessageFactory {
	return NewMessageFactoryWithRegistries(nil, ktr)
	}

	// NewMessageFactoryWithDefaults creates a new message factory where all "default" types
	// (those for which protoc-generated code is statically linked into the Go program) are
	// known types. If any dynamic messages are produced, they will recognize and parse all
	// "default" extension fields. This is the equivalent of:
	// NewMessageFactoryWithRegistries(
	// NewExtensionRegistryWithDefaults(),
	// NewKnownTypeRegistryWithDefaults())
	func NewMessageFactoryWithDefaults() *MessageFactory {
	return NewMessageFactoryWithRegistries(NewExtensionRegistryWithDefaults(), NewKnownTypeRegistryWithDefaults())
	}

	// NewMessageFactoryWithRegistries creates a new message factory with the given extension
	// and known type registries.
	func NewMessageFactoryWithRegistries(er ExtensionRegistry, ktr KnownTypeRegistry) *MessageFactory {
	return &MessageFactory{
	er: er,
	ktr: ktr,
	}
	}

	// NewMessage creates a new empty message that corresponds to the given descriptor.
	// If the given descriptor describes a "known type" then that type is instantiated.
	// Otherwise, an empty dynamic message is returned.
	func (f MessageFactory) NewMessage(md desc.MessageDescriptor) proto.Message {
	var ktr *KnownTypeRegistry
	if f != nil {
	ktr = f.ktr
	}
	if m := ktr.CreateIfKnown(md.GetFullyQualifiedName()); m != nil {
	return m
	}
	return NewMessageWithMessageFactory(md, f)
	}

	// NewDynamicMessage creates a new empty dynamic message that corresponds to the given
	// descriptor. This is like f.NewMessage(md) except the known type registry is not
	// consulted so the return value is always a dynamic message.
	//
	// This is also like dynamic.NewMessage(md) except that the returned message will use
	// this factory when creating other messages, like during de-serialization of fields
	// that are themselves message types.
	func (f MessageFactory) NewDynamicMessage(md desc.MessageDescriptor) *Message {
	return NewMessageWithMessageFactory(md, f)
	}

	// GetKnownTypeRegistry returns the known type registry that this factory uses to
	// instantiate known (e.g. generated) message types.
	func (f MessageFactory) GetKnownTypeRegistry() KnownTypeRegistry {
	if f == nil {
	return nil
	}
	return f.ktr
	}

	// GetExtensionRegistry returns the extension registry that this factory uses to
	// create dynamic messages. The registry is used by dynamic messages to recognize
	// and parse extension fields during de-serialization.
	func (f MessageFactory) GetExtensionRegistry() ExtensionRegistry {
	if f == nil {
	return nil
	}
	return f.er
	}

	type wkt interface {
	XXX_WellKnownType() string
	}

	var typeOfWkt = reflect.TypeOf((*wkt)(nil)).Elem()

	// KnownTypeRegistry is a registry of known message types, as identified by their
	// fully-qualified name. A known message type is one for which a protoc-generated
	// struct exists, so a dynamic message is not necessary to represent it. A
	// MessageFactory uses a KnownTypeRegistry to decide whether to create a generated
	// struct or a dynamic message. The zero-value registry (including the behavior of
	// a nil pointer) only knows about the "well-known types" in protobuf. These
	// include only the wrapper types and a handful of other special types like Any,
	// Duration, and Timestamp.
	type KnownTypeRegistry struct {
	excludeWkt bool
	includeDefault bool
	mu sync.RWMutex
	types map[string]reflect.Type
	}

	// NewKnownTypeRegistryWithDefaults creates a new registry that knows about all
	// "default" types (those for which protoc-generated code is statically linked
	// into the Go program).
	func NewKnownTypeRegistryWithDefaults() *KnownTypeRegistry {
	return &KnownTypeRegistry{includeDefault: true}
	}

	// NewKnownTypeRegistryWithoutWellKnownTypes creates a new registry that does not
	// include the "well-known types" in protobuf. So even well-known types would be
	// represented by a dynamic message.
	func NewKnownTypeRegistryWithoutWellKnownTypes() *KnownTypeRegistry {
	return &KnownTypeRegistry{excludeWkt: true}
	}

	// AddKnownType adds the types of the given messages as known types.
	func (r *KnownTypeRegistry) AddKnownType(kts ...proto.Message) {
	r.mu.Lock()
	defer r.mu.Unlock()
	if r.types == nil {
	r.types = map[string]reflect.Type{}
	}
	for _, kt := range kts {
	r.types[proto.MessageName(kt)] = reflect.TypeOf(kt)
	}
	}

	// CreateIfKnown will construct an instance of the given message if it is a known type.
	// If the given name is unknown, nil is returned.
	func (r *KnownTypeRegistry) CreateIfKnown(messageName string) proto.Message {
	msgType := r.GetKnownType(messageName)
	if msgType == nil {
	return nil
	}

	if msgType.Kind() == reflect.Ptr {
	return reflect.New(msgType.Elem()).Interface().(proto.Message)
	} else {
	return reflect.New(msgType).Elem().Interface().(proto.Message)
	}
	}

	func isWellKnownType(t reflect.Type) bool {
	if t.Implements(typeOfWkt) {
	return true
	}
	if msg, ok := reflect.Zero(t).Interface().(proto.Message); ok {
	name := proto.MessageName(msg)
	_, ok := wellKnownTypeNames[name]
	return ok
	}
	return false
	}

	// GetKnownType will return the reflect.Type for the given message name if it is
	// known. If it is not known, nil is returned.
	func (r *KnownTypeRegistry) GetKnownType(messageName string) reflect.Type {
	var msgType reflect.Type
	if r == nil {
	// a nil registry behaves the same as zero value instance: only know of well-known types
	t := proto.MessageType(messageName)
	if t != nil && isWellKnownType(t) {
	msgType = t
	}
	} else {
	if r.includeDefault {
	msgType = proto.MessageType(messageName)
	} else if !r.excludeWkt {
	t := proto.MessageType(messageName)
	if t != nil && isWellKnownType(t) {
	msgType = t
	}
	}
	if msgType == nil {
	r.mu.RLock()
	msgType = r.types[messageName]
	r.mu.RUnlock()
	}
	}

	return msgType
	}