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

 // Package dynamic provides an implementation for a dynamic protobuf message.
 //
 // The dynamic message is essentially a message descriptor along with a map of
 // tag numbers to values. It has a broad API for interacting with the message,
 // including inspection and modification. Generally, most operations have two
 // forms: a regular method that panics on bad input or error and a "Try" form
 // of the method that will instead return an error.
 //
 // A dynamic message can optionally be constructed with a MessageFactory. The
 // MessageFactory has various registries that may be used by the dynamic message,
 // such as during de-serialization. The message factory is "inherited" by any
 // other dynamic messages created, such as nested messages that are created
 // during de-serialization. Similarly, any dynamic message created using
 // MessageFactory.NewMessage will be associated with that factory, which in turn
 // will be used to create other messages or parse extension fields during
 // de-serialization.
 //
 //
 // Field Types
 //
 // The types of values expected by setters and returned by getters are the
 // same as protoc generates for scalar fields. For repeated fields, there are
 // methods for getting and setting values at a particular index or for adding
 // an element. Similarly, for map fields, there are methods for getting and
 // setting values for a particular key.
 //
 // If you use GetField for a repeated field, it will return a copy of all
 // elements as a slice []interface{}. Similarly, using GetField for a map field
 // will return a copy of all mappings as a map[interface{}]interface{}. You can
 // also use SetField to supply an entire slice or map for repeated or map fields.
 // The slice need not be []interface{} but can actually be typed according to
 // the field's expected type. For example, a repeated uint64 field can be set
 // using a slice of type []uint64.
 //
 // Descriptors for map fields describe them as repeated fields with a nested
 // message type. The nested message type is a special generated type that
 // represents a single mapping: key and value pair. The dynamic message has some
 // special affordances for this representation. For example, you can use
 // SetField to set a map field using a slice of these entry messages. Internally,
 // the slice of entries will be converted to an actual map. Similarly, you can
 // use AddRepeatedField with an entry message to add (or overwrite) a mapping.
 // However, you cannot use GetRepeatedField or SetRepeatedField to modify maps,
 // since those take numeric index arguments which are not relevant to maps
 // (since maps in Go have no defined ordering).
 //
 // When setting field values in dynamic messages, the type-checking is lenient
 // in that it accepts any named type with the right kind. So a string field can
 // be assigned to any type that is defined as a string. Enum fields require
 // int32 values (or any type that is defined as an int32).
 //
 // Unlike normal use of numeric values in Go, values will be automatically
 // widened when assigned. So, for example, an int64 field can be set using an
 // int32 value since it can be safely widened without truncation or loss of
 // precision. Similar goes for uint32 values being converted to uint64 and
 // float32 being converted to float64. Narrowing conversions are not done,
 // however. Also, unsigned values will never be automatically converted to
 // signed (and vice versa), and floating point values will never be
 // automatically converted to integral values (and vice versa). Since the bit
 // width of int and uint fields is allowed to be platform dependent, but will
 // always be less than or equal to 64, they can only be used as values for
 // int64 and uint64 fields, respectively. They cannot be used to set int32 or
 // uint32 fields, which includes enums fields.
 //
 // Fields whose type is a nested message can have values set to either other
 // dynamic messages or generated messages (e.g. pointers to structs generated by
 // protoc). Getting a value for such a field will return the actual type it is
 // set to (e.g. either a dynamic message or a generated message). If the value
 // is not set and the message uses proto2 syntax, the default message returned
 // will be whatever is returned by the dynamic message's MessageFactory (if the
 // dynamic message was not created with a factory, it will use the logic of the
 // zero value factory). In most typical cases, it will return a dynamic message,
 // but if the factory is configured with a KnownTypeRegistry, or if the field's
 // type is a well-known type, it will return a zero value generated message.
 //
 //
 // Unrecognized Fields
 //
 // Unrecognized fields are preserved by the dynamic message when unmarshaling
 // from the standard binary format. If the message's MessageFactory was
 // configured with an ExtensionRegistry, it will be used to identify and parse
 // extension fields for the message.
 //
 // Unrecognized fields can dynamically become recognized fields if the
 // application attempts to retrieve an unrecognized field's value using a
 // FieldDescriptor. In this case, the given FieldDescriptor is used to parse the
 // unknown field and move the parsed value into the message's set of known
 // fields. This behavior is most suited to the use of extensions, where an
 // ExtensionRegistry is not setup with all known extensions ahead of time. But
 // it can even happen for non-extension fields! Here's an example scenario where
 // a non-extension field can initially be unknown and become known:
 //
 //   1. A dynamic message is created with a descriptor, A, and then
 //      de-serialized from a stream of bytes. The stream includes an
 //      unrecognized tag T. The message will include tag T in its unrecognized
 //      field set.
 //   2. Another call site retrieves a newer descriptor, A', which includes a
 //      newly added field with tag T.
 //   3. That other call site then uses a FieldDescriptor to access the value of
 //      the new field. This will cause the dynamic message to parse the bytes
 //      for the unknown tag T and store them as a known field.
 //   4. Subsequent operations for tag T, including setting the field using only
 //      tag number or de-serializing a stream that includes tag T, will operate
 //      as if that tag were part of the original descriptor, A.
 //
 //
 // Compatibility
 //
 // In addition to implementing the proto.Message interface, the included
 // Message type also provides an XXX_MessageName() method, so it can work with
 // proto.MessageName. And it provides a Descriptor() method that behaves just
 // like the method of the same signature in messages generated by protoc.
 // Because of this, it is actually compatible with proto.Message in many (though
 // not all) contexts. In particular, it is compatible with proto.Marshal and
 // proto.Unmarshal for serializing and de-serializing messages.
 //
 // The dynamic message supports binary and text marshaling, using protobuf's
 // well-defined binary format and the same text format that protoc-generated
 // types use. It also supports JSON serialization/de-serialization by
 // implementing the json.Marshaler and json.Unmarshaler interfaces. And dynamic
 // messages can safely be used with the jsonpb package for JSON serialization
 // and de-serialization.
 //
 // In addition to implementing the proto.Message interface and numerous related
 // methods, it also provides inter-op with generated messages via conversion.
 // The ConvertTo, ConvertFrom, MergeInto, and MergeFrom methods copy message
 // contents from a dynamic message to a generated message and vice versa.
 //
 // When copying from a generated message into a dynamic message, if the
 // generated message contains fields unknown to the dynamic message (e.g. not
 // present in the descriptor used to create the dynamic message), these fields
 // become known to the dynamic message (as per behavior described above in
 // "Unrecognized Fields"). If the generated message has unrecognized fields of
 // its own, including unrecognized extensions, they are preserved in the dynamic
 // message. It is possible that the dynamic message knows about fields that the
 // generated message did not, like if it has a different version of the
 // descriptor or its MessageFactory has an ExtensionRegistry that knows about
 // different extensions than were linked into the program. In this case, these
 // unrecognized fields in the generated message will be known fields in the
 // dynamic message.
 //
 // Similarly, when copying from a dynamic message into a generated message, if
 // the dynamic message has unrecognized fields they can be preserved in the
 // generated message (currently only for syntax proto2 since proto3 generated
 // messages do not preserve unrecognized fields). If the generated message knows
 // about fields that the dynamic message does not, these unrecognized fields may
 // become known fields in the generated message.
 //
 //
 // Registries
 //
 // This package also contains a couple of registries, for managing known types
 // and descriptors.
 //
 // The KnownTypeRegistry allows de-serialization of a dynamic message to use
 // generated message types, instead of dynamic messages, for some kinds of
 // nested message fields. This is particularly useful for working with proto
 // messages that have special encodings as JSON (e.g. the well-known types),
 // since the dynamic message does not try to handle these special cases in its
 // JSON marshaling facilities.
 //
 // The ExtensionRegistry allows for recognizing and parsing extensions fields
 // (for proto2 messages).
 package dynamic
	// Package dynamic provides an implementation for a dynamic protobuf message.
	//
	// The dynamic message is essentially a message descriptor along with a map of
	// tag numbers to values. It has a broad API for interacting with the message,
	// including inspection and modification. Generally, most operations have two
	// forms: a regular method that panics on bad input or error and a "Try" form
	// of the method that will instead return an error.
	//
	// A dynamic message can optionally be constructed with a MessageFactory. The
	// MessageFactory has various registries that may be used by the dynamic message,
	// such as during de-serialization. The message factory is "inherited" by any
	// other dynamic messages created, such as nested messages that are created
	// during de-serialization. Similarly, any dynamic message created using
	// MessageFactory.NewMessage will be associated with that factory, which in turn
	// will be used to create other messages or parse extension fields during
	// de-serialization.
	//
	//
	// Field Types
	//
	// The types of values expected by setters and returned by getters are the
	// same as protoc generates for scalar fields. For repeated fields, there are
	// methods for getting and setting values at a particular index or for adding
	// an element. Similarly, for map fields, there are methods for getting and
	// setting values for a particular key.
	//
	// If you use GetField for a repeated field, it will return a copy of all
	// elements as a slice []interface{}. Similarly, using GetField for a map field
	// will return a copy of all mappings as a map[interface{}]interface{}. You can
	// also use SetField to supply an entire slice or map for repeated or map fields.
	// The slice need not be []interface{} but can actually be typed according to
	// the field's expected type. For example, a repeated uint64 field can be set
	// using a slice of type []uint64.
	//
	// Descriptors for map fields describe them as repeated fields with a nested
	// message type. The nested message type is a special generated type that
	// represents a single mapping: key and value pair. The dynamic message has some
	// special affordances for this representation. For example, you can use
	// SetField to set a map field using a slice of these entry messages. Internally,
	// the slice of entries will be converted to an actual map. Similarly, you can
	// use AddRepeatedField with an entry message to add (or overwrite) a mapping.
	// However, you cannot use GetRepeatedField or SetRepeatedField to modify maps,
	// since those take numeric index arguments which are not relevant to maps
	// (since maps in Go have no defined ordering).
	//
	// When setting field values in dynamic messages, the type-checking is lenient
	// in that it accepts any named type with the right kind. So a string field can
	// be assigned to any type that is defined as a string. Enum fields require
	// int32 values (or any type that is defined as an int32).
	//
	// Unlike normal use of numeric values in Go, values will be automatically
	// widened when assigned. So, for example, an int64 field can be set using an
	// int32 value since it can be safely widened without truncation or loss of
	// precision. Similar goes for uint32 values being converted to uint64 and
	// float32 being converted to float64. Narrowing conversions are not done,
	// however. Also, unsigned values will never be automatically converted to
	// signed (and vice versa), and floating point values will never be
	// automatically converted to integral values (and vice versa). Since the bit
	// width of int and uint fields is allowed to be platform dependent, but will
	// always be less than or equal to 64, they can only be used as values for
	// int64 and uint64 fields, respectively. They cannot be used to set int32 or
	// uint32 fields, which includes enums fields.
	//
	// Fields whose type is a nested message can have values set to either other
	// dynamic messages or generated messages (e.g. pointers to structs generated by
	// protoc). Getting a value for such a field will return the actual type it is
	// set to (e.g. either a dynamic message or a generated message). If the value
	// is not set and the message uses proto2 syntax, the default message returned
	// will be whatever is returned by the dynamic message's MessageFactory (if the
	// dynamic message was not created with a factory, it will use the logic of the
	// zero value factory). In most typical cases, it will return a dynamic message,
	// but if the factory is configured with a KnownTypeRegistry, or if the field's
	// type is a well-known type, it will return a zero value generated message.
	//
	//
	// Unrecognized Fields
	//
	// Unrecognized fields are preserved by the dynamic message when unmarshaling
	// from the standard binary format. If the message's MessageFactory was
	// configured with an ExtensionRegistry, it will be used to identify and parse
	// extension fields for the message.
	//
	// Unrecognized fields can dynamically become recognized fields if the
	// application attempts to retrieve an unrecognized field's value using a
	// FieldDescriptor. In this case, the given FieldDescriptor is used to parse the
	// unknown field and move the parsed value into the message's set of known
	// fields. This behavior is most suited to the use of extensions, where an
	// ExtensionRegistry is not setup with all known extensions ahead of time. But
	// it can even happen for non-extension fields! Here's an example scenario where
	// a non-extension field can initially be unknown and become known:
	//
	// 1. A dynamic message is created with a descriptor, A, and then
	// de-serialized from a stream of bytes. The stream includes an
	// unrecognized tag T. The message will include tag T in its unrecognized
	// field set.
	// 2. Another call site retrieves a newer descriptor, A', which includes a
	// newly added field with tag T.
	// 3. That other call site then uses a FieldDescriptor to access the value of
	// the new field. This will cause the dynamic message to parse the bytes
	// for the unknown tag T and store them as a known field.
	// 4. Subsequent operations for tag T, including setting the field using only
	// tag number or de-serializing a stream that includes tag T, will operate
	// as if that tag were part of the original descriptor, A.
	//
	//
	// Compatibility
	//
	// In addition to implementing the proto.Message interface, the included
	// Message type also provides an XXX_MessageName() method, so it can work with
	// proto.MessageName. And it provides a Descriptor() method that behaves just
	// like the method of the same signature in messages generated by protoc.
	// Because of this, it is actually compatible with proto.Message in many (though
	// not all) contexts. In particular, it is compatible with proto.Marshal and
	// proto.Unmarshal for serializing and de-serializing messages.
	//
	// The dynamic message supports binary and text marshaling, using protobuf's
	// well-defined binary format and the same text format that protoc-generated
	// types use. It also supports JSON serialization/de-serialization by
	// implementing the json.Marshaler and json.Unmarshaler interfaces. And dynamic
	// messages can safely be used with the jsonpb package for JSON serialization
	// and de-serialization.
	//
	// In addition to implementing the proto.Message interface and numerous related
	// methods, it also provides inter-op with generated messages via conversion.
	// The ConvertTo, ConvertFrom, MergeInto, and MergeFrom methods copy message
	// contents from a dynamic message to a generated message and vice versa.
	//
	// When copying from a generated message into a dynamic message, if the
	// generated message contains fields unknown to the dynamic message (e.g. not
	// present in the descriptor used to create the dynamic message), these fields
	// become known to the dynamic message (as per behavior described above in
	// "Unrecognized Fields"). If the generated message has unrecognized fields of
	// its own, including unrecognized extensions, they are preserved in the dynamic
	// message. It is possible that the dynamic message knows about fields that the
	// generated message did not, like if it has a different version of the
	// descriptor or its MessageFactory has an ExtensionRegistry that knows about
	// different extensions than were linked into the program. In this case, these
	// unrecognized fields in the generated message will be known fields in the
	// dynamic message.
	//
	// Similarly, when copying from a dynamic message into a generated message, if
	// the dynamic message has unrecognized fields they can be preserved in the
	// generated message (currently only for syntax proto2 since proto3 generated
	// messages do not preserve unrecognized fields). If the generated message knows
	// about fields that the dynamic message does not, these unrecognized fields may
	// become known fields in the generated message.
	//
	//
	// Registries
	//
	// This package also contains a couple of registries, for managing known types
	// and descriptors.
	//
	// The KnownTypeRegistry allows de-serialization of a dynamic message to use
	// generated message types, instead of dynamic messages, for some kinds of
	// nested message fields. This is particularly useful for working with proto
	// messages that have special encodings as JSON (e.g. the well-known types),
	// since the dynamic message does not try to handle these special cases in its
	// JSON marshaling facilities.
	//
	// The ExtensionRegistry allows for recognizing and parsing extensions fields
	// (for proto2 messages).
	package dynamic