+++ title = "Java Generated Code Guide" weight = 650 linkTitle = "Generated Code Guide" description = "Describes exactly what Java code the protocol buffer compiler generates for any given protocol definition." type = "docs" +++ Any differences between proto2 and proto3 generated code are highlighted—note that these differences are in the generated code as described in this document, not the base message classes/interfaces, which are the same in both versions. You should read the [proto2 language guide](/programming-guides/proto2) and/or [proto3 language guide](/programming-guides/proto3) before reading this document. Note that no Java protocol buffer methods accept or return nulls unless otherwise specified. ## Compiler Invocation {#invocation} The protocol buffer compiler produces Java output when invoked with the `--java_out=` command-line flag. The parameter to the `--java_out=` option is the directory where you want the compiler to write your Java output. For each `.proto` file input, the compiler creates a wrapper `.java` file containing a Java class that represents the `.proto` file itself. If the `.proto` file contains a line like the following: ```proto option java_multiple_files = true; ``` Then the compiler will also create separate `.java` files for each of the classes/enums which it will generate for each top-level message, enumeration, and service declared in the `.proto` file. Otherwise (when the `java_multiple_files` option is disabled, which is the default), the aforementioned wrapper class will also be used as an outer class, and the generated classes/enums for each top-level message, enumeration, and service declared in the `.proto` file will all be nested within the outer wrapper class. Thus the compiler will only generate a single `.java` file for the entire `.proto` file, and it will have an extra layer in the package The wrapper class's name is chosen as follows: If the `.proto` file contains a line like the following: ```proto option java_outer_classname = "Foo"; ``` Then the wrapper class name will be `Foo`. Otherwise, the wrapper class name is determined by converting the `.proto` file base name to camel case. For example, `foo_bar.proto` will generate a class name of `FooBar`. If there's a service, enum, or message (including nested types) in the file with the same name, "OuterClass" will be appended to the wrapper class's name. Examples: - If `foo_bar.proto` contains a message called `FooBar`, the wrapper class will generate a class name of `FooBarOuterClass`. - If `foo_bar.proto` contains a service called `FooService`, and `java_outer_classname` is also set to the string `FooService`, then the wrapper class will generate a class name of `FooServiceOuterClass`. {{% alert title="Note" color="note" %}}If you are using the deprecated v1 of the protobuf API, `OuterClass` is added regardless of any collisions with message names.{{% /alert %}} In addition to any nested classes, the wrapper class itself will have the following API (assuming the wrapper class is named `Foo` and was generated from `foo.proto`): ```java public final class Foo { private Foo() {} // Not instantiable. /** Returns a FileDescriptor message describing the contents of {@code foo.proto}. */ public static com.google.protobuf.Descriptors.FileDescriptor getDescriptor(); /** Adds all extensions defined in {@code foo.proto} to the given registry. */ public static void registerAllExtensions(com.google.protobuf.ExtensionRegistry registry); public static void registerAllExtensions(com.google.protobuf.ExtensionRegistryLite registry); // (Nested classes omitted) } ``` The Java package name is chosen as described under [Packages](#package), below. The output file is chosen by concatenating the parameter to `--java_out=`, the package name (with `.`s replaced with `/`s), and the `.java` file name. So, for example, let's say you invoke the compiler as follows: ```shell protoc --proto_path=src --java_out=build/gen src/foo.proto ``` If `foo.proto`'s Java package is `com.example` and it doesn't enable `java_multiple_files` and its outer classname is `FooProtos`, then the protocol buffer compiler will generate the file `build/gen/com/example/FooProtos.java`. The protocol buffer compiler will automatically create the `build/gen/com` and `build/gen/com/example` directories if needed. However, it will not create `build/gen` or `build`; they must already exist. You can specify multiple `.proto` files in a single invocation; all output files will be generated at once. When outputting Java code, the protocol buffer compiler's ability to output directly to JAR archives is particularly convenient, as many Java tools are able to read source code directly from JAR files. To output to a JAR file, simply provide an output location ending in `.jar`. Note that only the Java source code is placed in the archive; you must still compile it separately to produce Java class files. ## Packages {#package} The generated class is placed in a Java package based on the `java_package` option. If the option is omitted, the `package` declaration is used instead. For example, if the `.proto` file contains: ```proto package foo.bar; ``` Then the resulting Java class will be placed in Java package `foo.bar`. However, if the `.proto` file also contains a `java_package` option, like so: ```proto package foo.bar; option java_package = "com.example.foo.bar"; ``` Then the class is placed in the `com.example.foo.bar` package instead. The `java_package` option is provided because normal `.proto` `package` declarations are not expected to start with a backwards domain name. ## Messages {#message} If you are designing a new protocol buffer schema, see [the recommendations for Java proto names](/reference/java/java-proto-names). Given a simple message declaration: ```proto message Foo {} ``` The protocol buffer compiler generates a class called `Foo`, which implements the `Message` interface. The class is declared `final`; no further subclassing is allowed. `Foo` extends `GeneratedMessage`, but this should be considered an implementation detail. By default, `Foo` overrides many methods of `GeneratedMessage` with specialized versions for maximum speed. However, if the `.proto` file contains the line: ```proto option optimize_for = CODE_SIZE; ``` then `Foo` will override only the minimum set of methods necessary to function and rely on `GeneratedMessage`'s reflection-based implementations of the rest. This significantly reduces the size of the generated code, but also reduces performance. Alternatively, if the `.proto` file contains: ```proto option optimize_for = LITE_RUNTIME; ``` then `Foo` will include fast implementations of all methods, but will implement the `MessageLite` interface, which contains a subset of the methods of `Message`. In particular, it does not support descriptors, nested builders, or reflection. However, in this mode, the generated code only needs to link against `libprotobuf-lite.jar` instead of `libprotobuf.jar`. The "lite" library is much smaller than the full library, and is more appropriate for resource-constrained systems such as mobile phones. The `Message` interface defines methods that let you check, manipulate, read, or write the entire message. In addition to these methods, the `Foo` class defines the following static methods: - `static Foo getDefaultInstance()`: Returns the *singleton* instance of `Foo`. This instance's contents are identical to what you'd get if you called `Foo.newBuilder().build()` (so all singular fields are unset and all repeated fields are empty). Note that the default instance of a message can be used as a factory by calling its `newBuilderForType()` method. - `static Descriptor getDescriptor()`: Returns the type's descriptor. This contains information about the type, including what fields it has and what their types are. This can be used with the reflection methods of the `Message`, such as `getField()`. - `static Foo parseFrom(...)`: Parses a message of type `Foo` from the given source and returns it. There is one `parseFrom` method corresponding to each variant of `mergeFrom()` in the `Message.Builder` interface. Note that `parseFrom()` never throws `UninitializedMessageException`; it throws `InvalidProtocolBufferException` if the parsed message is missing required fields. This makes it subtly different from calling `Foo.newBuilder().mergeFrom(...).build()`. - `static Parser parser()`: Returns an instance of the `Parser`, which implements various `parseFrom()` methods. - `Foo.Builder newBuilder()`: Creates a new builder (described below). - `Foo.Builder newBuilder(Foo prototype)`: Creates a new builder with all fields initialized to the same values that they have in `prototype`. Since embedded message and string objects are immutable, they are shared between the original and the copy. ### Builders {#builders} Message objects—such as instances of the `Foo` class described above—are immutable, just like a Java `String`. To construct a message object, you need to use a *builder*. Each message class has its own builder class—so in our `Foo` example, the protocol buffer compiler generates a nested class `Foo.Builder` which can be used to build a `Foo`. `Foo.Builder` implements the `Message.Builder` interface. It extends the `GeneratedMessage.Builder` class, but, again, this should be considered an implementation detail. Like `Foo`, `Foo.Builder` may rely on generic method implementations in `GeneratedMessage.Builder` or, when the `optimize_for` option is used, generated custom code that is much faster. You can get a `Foo.Builder` by calling the static method `Foo.newBuilder()`. `Foo.Builder` does not define any static methods. Its interface is exactly as defined by the `Message.Builder` interface, with the exception that return types are more specific: methods of `Foo.Builder` that modify the builder return type `Foo.Builder`, and `build()` returns type `Foo`. Methods that modify the contents of a builder—including field setters—always return a reference to the builder (i.e. they "`return this;`"). This allows multiple method calls to be chained together in one line. For example: `builder.mergeFrom(obj).setFoo(1).setBar("abc").clearBaz();` Note that builders are not thread-safe, so Java synchronization should be used whenever it is necessary for multiple different threads to be modifying the contents of a single builder. ### Sub-Builders {#sub-builders} For messages containing sub-messages, the compiler also generates sub-builders. This allows you to repeatedly modify deep-nested sub-messages without rebuilding them. For example: ```proto message Foo { optional int32 val = 1; // some other fields. } message Bar { optional Foo foo = 1; // some other fields. } message Baz { optional Bar bar = 1; // some other fields. } ``` If you have a `Baz` message already, and want to change the deeply nested `val` in `Foo`. Instead of: ```java baz = baz.toBuilder().setBar( baz.getBar().toBuilder().setFoo( baz.getBar().getFoo().toBuilder().setVal(10).build() ).build()).build(); ``` You can write: ```java Baz.Builder builder = baz.toBuilder(); builder.getBarBuilder().getFooBuilder().setVal(10); baz = builder.build(); ``` ### Nested Types {#nested} A message can be declared inside another message. For example: ```proto message Foo { message Bar { } } ``` In this case, the compiler simply generates `Bar` as an inner class nested inside `Foo`. ## Fields {#fields} In addition to the methods described in the previous section, the protocol buffer compiler generates a set of accessor methods for each field defined within the message in the `.proto` file. The methods that read the field value are defined both in the message class and its corresponding builder; the methods that modify the value are defined in the builder only. Note that method names always use camel-case naming, even if the field name in the `.proto` file uses lower-case with underscores ([as it should](/programming-guides/style)). The case-conversion works as follows: * For each underscore in the name, the underscore is removed, and the following letter is capitalized. * If the name will have a prefix attached (e.g. "get"), the first letter is capitalized. Otherwise, it is lower-cased. * The letter following the last digit in each number in a method name is capitalized. Thus, the field `foo_bar_baz` becomes `fooBarBaz`. If prefixed with `get`, it would be `getFooBarBaz`. And `foo_ba23r_baz` becomes `fooBa23RBaz`. As well as accessor methods, the compiler generates an integer constant for each field containing its field number. The constant name is the field name converted to upper-case followed by `_FIELD_NUMBER`. For example, given the field `optional int32 foo_bar = 5;`, the compiler will generate the constant `public static final int FOO_BAR_FIELD_NUMBER = 5;`. ### Singular Fields (proto2) {#singular-proto2} For any of these field definitions: ```proto optional int32 foo = 1; required int32 foo = 1; ``` The compiler will generate the following accessor methods in both the message class and its builder: - `boolean hasFoo()`: Returns `true` if the field is set. - `int getFoo()`: Returns the current value of the field. If the field is not set, returns the default value. The compiler will generate the following methods only in the message's builder: - `Builder setFoo(int value)`: Sets the value of the field. After calling this, `hasFoo()` will return `true` and `getFoo()` will return `value`. - `Builder clearFoo()`: Clears the value of the field. After calling this, `hasFoo()` will return `false` and `getFoo()` will return the default value. For other simple field types, the corresponding Java type is chosen according to the [scalar value types table](/programming-guides/proto2#scalar). For message and enum types, the value type is replaced with the message or enum class. #### Embedded Message Fields {#embedded-message-proto2} For message types, `setFoo()` also accepts an instance of the message's builder type as the parameter. This is just a shortcut which is equivalent to calling `.build()` on the builder and passing the result to the method. Further modifying the sub-builder passed to `setFoo` will **not** be reflected in the message class's builder. The message class's builder "takes ownership" of the sub-message. If the field is not set, `getFoo()` will return a Foo instance with none of its fields set (possibly the instance returned by `Foo.getDefaultInstance()`). In addition, the compiler generates two accessor methods that allow you to access the relevant sub-builders for message types. The following method is generated in both the message class and its builder: - `FooOrBuilder getFooOrBuilder()`: Returns the builder for the field, if it already exists, or the message if not. Calling this method on builders will not create a sub-builder for the field. The compiler generates the following method only in the message's builder. - `Builder getFooBuilder()`: Returns the builder for the field. ### Singular Fields (proto3) {#singular-proto3} For this field definition: ```proto int32 foo = 1; ``` The compiler will generate the following accessor method in both the message class and its builder: - `int getFoo()`: Returns the current value of the field. If the field is not set, returns the default value for the field's type. The compiler will generate the following methods only in the message's builder: - `Builder setFoo(int value)`: Sets the value of the field. After calling this, `getFoo()` will return `value`. - `Builder clearFoo()`: Clears the value of the field. After calling this, `getFoo()` will return the default value for the field's type. For other simple field types, the corresponding Java type is chosen according to the [scalar value types table](/programming-guides/proto2#scalar). For message and enum types, the value type is replaced with the message or enum class. #### Embedded Message Fields {#embedded-message-proto3} For message field types, an additional accessor method is generated in both the message class and its builder: - `boolean hasFoo()`: Returns `true` if the field has been set. `setFoo()` also accepts an instance of the message's builder type as the parameter. This is just a shortcut which is equivalent to calling `.build()` on the builder and passing the result to the method. If the field is not set, `getFoo()` will return a Foo instance with none of its fields set (possibly the instance returned by `Foo.getDefaultInstance()`). In addition, the compiler generates two accessor methods that allow you to access the relevant sub-builders for message types. The following method is generated in both the message class and its builder: - `FooOrBuilder getFooOrBuilder()`: Returns the builder for the field, if it already exists, or the message if not. Calling this method on builders will not create a sub-builder for the field. The compiler generates the following method only in the message's builder. - `Builder getFooBuilder()`: Returns the builder for the field. #### Enum Fields {#enum-proto3} For enum field types, an additional accessor method is generated in both the message class and its builder: - `int getFooValue()`: Returns the integer value of the enum. The compiler will generate the following additional method only in the message's builder: - `Builder setFooValue(int value)`: Sets the integer value of the enum. In addition, `getFoo()` will return `UNRECOGNIZED` if the enum value is unknown—this is a special additional value added by the proto3 compiler to the generated [enum type](#enum). ### Repeated Fields {#repeated} For this field definition: ```proto repeated string foos = 1; ``` The compiler will generate the following accessor methods in both the message class and its builder: - `int getFoosCount()`: Returns the number of elements currently in the field. - `String getFoos(int index)`: Returns the element at the given zero-based index. - `ProtocolStringList getFoosList()`: Returns the entire field as a `ProtocolStringList`. If the field is not set, returns an empty list. The compiler will generate the following methods only in the message's builder: - `Builder setFoos(int index, String value)`: Sets the value of the element at the given zero-based index. - `Builder addFoos(String value)`: Appends a new element to the field with the given value. - `Builder addAllFoos(Iterable value)`: Appends all elements in the given `Iterable` to the field. - `Builder clearFoos()`: Removes all elements from the field. After calling this, `getFoosCount()` will return zero. For other simple field types, the corresponding Java type is chosen according to the [scalar value types table](/programming-guides/proto2#scalar). For message and enum types, the type is the message or enum class. #### Repeated Embedded Message Fields {#repeated-embedded} For message types, `setFoos()` and `addFoos()` also accept an instance of the message's builder type as the parameter. This is just a shortcut which is equivalent to calling `.build()` on the builder and passing the result to the method. There is also an additional generated method: - `Builder addFoos(int index, Field value)`: Inserts a new element at the given zero-based index. Shifts the element currently at that position (if any) and any subsequent elements to the right (adds one to their indices). In addition, the compiler generates the following additional accessor methods in both the message class and its builder for message types, allowing you to access the relevant sub-builders: - `FooOrBuilder getFoosOrBuilder(int index)`: Returns the builder for the specified element, if it already exists, or throws `IndexOutOfBoundsException` if not. If this is called from a message class, it will always return a message (or throw an exception) rather than a builder. Calling this method on builders will not create a sub-builder for the field. - `List getFoosOrBuilderList()`: Returns the entire field as an unmodifiable list of builders (if available) or messages if not. If this is called from a message class, it will always return an immutable list of messages rather than an unmodifiable list of builders. The compiler will generate the following methods only in the message's builder: - `Builder getFoosBuilder(int index)`: Returns the builder for the element at the specified index, or throws `IndexOutOfBoundsException` if the index is out of bounds. - `Builder addFoosBuilder(int index)`: Inserts and returns a builder for a default message instance of the repeated message at the specified index. The existing entries are shifted to higher indices to make room for the inserted builder. - `Builder addFoosBuilder()`: Appends and returns a builder for a default message instance of the repeated message. - `Builder removeFoos(int index)`: Removes the element at the given zero-based index. - `List getFoosBuilderList()`: Returns the entire field as an unmodifiable list of builders. #### Repeated Enum Fields (proto3 only) {#repeated-enum-proto3} The compiler will generate the following additional methods in both the message class and its builder: - `int getFoosValue(int index)`: Returns the integer value of the enum at the specified index. - `List getFoosValueList()`: Returns the entire field as a list of Integers. The compiler will generate the following additional method only in the message's builder: - `Builder setFoosValue(int index, int value)`: Sets the integer value of the enum at the specified index. #### Name Conflicts {#conflicts} If another non-repeated field has a name that conflicts with one of the repeated field's generated methods, then both field names will have their protobuf field number appended to the end. For these field definitions: ```proto int32 foos_count = 1; repeated string foos = 2; ``` The compiler will first rename them to the following: ```proto int32 foos_count_1 = 1; repeated string foos_2 = 2; ``` The accessor methods will subsequently be generated as described above. ### Oneof Fields {#oneof-fields} For this oneof field definition: ```proto oneof choice { int32 foo_int = 4; string foo_string = 9; ... } ``` All the fields in the `choice` oneof will use a single private field for their value. In addition, the protocol buffer compiler will generate a Java enum type for the oneof case, as follows: ```java public enum ChoiceCase implements com.google.protobuf.Internal.EnumLite { FOO_INT(4), FOO_STRING(9), ... CHOICE_NOT_SET(0); ... }; ``` The values of this enum type have the following special methods: - `int getNumber()`: Returns the object's numeric value as defined in the .proto file. - `static ChoiceCase forNumber(int value)`: Returns the enum object corresponding to the given numeric value (or `null` for other numeric values). The compiler will generate the following accessor methods in both the message class and its builder: - `boolean hasFooInt()`: Returns `true` if the oneof case is `FOO_INT`. - `int getFooInt()`: Returns the current value of `foo` if the oneof case is `FOO_INT`. Otherwise, returns the default value of this field. - `ChoiceCase getChoiceCase()`: Returns the enum indicating which field is set. Returns `CHOICE_NOT_SET` if none of them is set. The compiler will generate the following methods only in the message's builder: - `Builder setFooInt(int value)`: Sets `Foo` to this value and sets the oneof case to `FOO_INT`. After calling this, `hasFooInt()` will return `true`, `getFooInt()` will return `value` and `getChoiceCase()` will return `FOO_INT`. - `Builder clearFooInt()`: - Nothing will be changed if the oneof case is not `FOO_INT`. - If the oneof case is `FOO_INT`, sets `Foo` to null and the oneof case to `CHOICE_NOT_SET`. After calling this, `hasFooInt()` will return `false`, `getFooInt()` will return the default value and `getChoiceCase()` will return `CHOICE_NOT_SET`. - `Builder.clearChoice()`: Resets the value for `choice`, returning the builder. For other simple field types, the corresponding Java type is chosen according to the [scalar value types table](/programming-guides/proto2#scalar). For message and enum types, the value type is replaced with the message or enum class. ### Map Fields {#map-fields} For this map field definition: ```proto map weight = 1; ``` The compiler will generate the following accessor methods in both the message class and its builder: - `Map getWeightMap();`: Returns an unmodifiable `Map`. - `int getWeightOrDefault(int key, int default);`: Returns the value for key or the default value if not present. - `int getWeightOrThrow(int key);`: Returns the value for key or throws IllegalArgumentException if not present. - `boolean containsWeight(int key);`: Indicates if the key is present in this field. - `int getWeightCount();`: Returns the number of elements in the map. The compiler will generate the following methods only in the message's builder: - `Builder putWeight(int key, int value);`: Add the weight to this field. - `Builder putAllWeight(Map value);`: Adds all entries in the given map to this field. - `Builder removeWeight(int key);`: Removes the weight from this field. - `Builder clearWeight();`: Removes all weights from this field. - `@Deprecated Map getMutableWeight();`: Returns a mutable `Map`. Note that multiple calls to this method may return different map instances. The returned map reference may be invalidated by any subsequent method calls to the Builder. #### Message Value Map Fields {#message-value-map-fields} For maps with message types as values, the compiler will generate an additional method in the message's builder: - `Foo.Builder putFooBuilderIfAbsent(int key);`: Ensures that `key` is present in the mapping, and inserts a new `Foo.Builder` if one does not already exist. Changes to the returned `Foo.Builder` will be reflected in the final message. ## Any {#any-fields} Given an [`Any`](/programming-guides/proto3#any) field like this: ```proto import "google/protobuf/any.proto"; message ErrorStatus { string message = 1; google.protobuf.Any details = 2; } ``` In our generated code, the getter for the `details` field returns an instance of `com.google.protobuf.Any`. This provides the following special methods to pack and unpack the `Any`'s values: ```java class Any { // Packs the given message into an Any using the default type URL // prefix “type.googleapis.com”. public static Any pack(Message message); // Packs the given message into an Any using the given type URL // prefix. public static Any pack(Message message, String typeUrlPrefix); // Checks whether this Any message’s payload is the given type. public boolean is(class clazz); // Unpacks Any into the given message type. Throws exception if // the type doesn’t match or parsing the payload has failed. public T unpack(class clazz) throws InvalidProtocolBufferException; } ``` ## Enumerations {#enum} Given an enum definition like: ```proto enum Foo { VALUE_A = 0; VALUE_B = 5; VALUE_C = 1234; } ``` The protocol buffer compiler will generate a Java enum type called `Foo` with the same set of values. If you are using proto3, it also adds the special value `UNRECOGNIZED` to the enum type. The values of the generated enum type have the following special methods: - `int getNumber()`: Returns the object's numeric value as defined in the `.proto` file. - `EnumValueDescriptor getValueDescriptor()`: Returns the value's descriptor, which contains information about the value's name, number, and type. - `EnumDescriptor getDescriptorForType()`: Returns the enum type's descriptor, which contains e.g. information about each defined value. Additionally, the `Foo` enum type contains the following static methods: - `static Foo forNumber(int value)`: Returns the enum object corresponding to the given numeric value. Returns null when there is no corresponding enum object. - `static Foo valueOf(int value)`: Returns the enum object corresponding to the given numeric value. This method is deprecated in favor of `forNumber(int value)` and will be removed in an upcoming release. - `static Foo valueOf(EnumValueDescriptor descriptor)`: Returns the enum object corresponding to the given value descriptor. May be faster than `valueOf(int)`. In proto3 returns `UNRECOGNIZED` if passed an unknown value descriptor. - `EnumDescriptor getDescriptor()`: Returns the enum type's descriptor, which contains e.g. information about each defined value. (This differs from `getDescriptorForType()` only in that it is a static method.) An integer constant is also generated with the suffix \_VALUE for each enum value. Note that the `.proto` language allows multiple enum symbols to have the same numeric value. Symbols with the same numeric value are synonyms. For example: ```proto enum Foo { BAR = 0; BAZ = 0; } ``` In this case, `BAZ` is a synonym for `BAR`. In Java, `BAZ` will be defined as a static final field like so: ```java static final Foo BAZ = BAR; ``` Thus, `BAR` and `BAZ` compare equal, and `BAZ` should never appear in switch statements. The compiler always chooses the first symbol defined with a given numeric value to be the "canonical" version of that symbol; all subsequent symbols with the same number are just aliases. An enum can be defined nested within a message type. The compiler generates the Java enum definition nested within that message type's class. **Caution: when generating Java code, the maximum number of values in a protobuf enum may be surprisingly low**—in the worst case, the maximum is slightly over 1,700 values. This limit is due to per-method size limits for Java bytecode, and it varies across Java implementations, different versions of the protobuf suite, and any options set on the enum in the `.proto` file. ## Extensions (proto2 only) {#extension} Given a message with an extension range: ```proto message Foo { extensions 100 to 199; } ``` The protocol buffer compiler will make `Foo` extend `GeneratedMessage.ExtendableMessage` instead of the usual `GeneratedMessage`. Similarly, `Foo`'s builder will extend `GeneratedMessage.ExtendableBuilder`. You should never refer to these base types by name (`GeneratedMessage` is considered an implementation detail). However, these superclasses define a number of additional methods that you can use to manipulate extensions. In particular `Foo` and `Foo.Builder` will inherit the methods `hasExtension()`, `getExtension()`, and `getExtensionCount()`. Additionally, `Foo.Builder` will inherit methods `setExtension()` and `clearExtension()`. Each of these methods takes, as its first parameter, an extension identifier (described below), which identifies an extension field. The remaining parameters and the return value are exactly the same as those for the corresponding accessor methods that would be generated for a normal (non-extension) field of the same type as the extension identifier. Given an extension definition: ```proto extend Foo { optional int32 bar = 123; } ``` The protocol buffer compiler generates an "extension identifier" called `bar`, which you can use with `Foo`'s extension accessors to access this extension, like so: ```java Foo foo = Foo.newBuilder() .setExtension(bar, 1) .build(); assert foo.hasExtension(bar); assert foo.getExtension(bar) == 1; ``` (The exact implementation of extension identifiers is complicated and involves magical use of generics—however, you don't need to worry about how extension identifiers work to use them.) Note that `bar` would be declared as a static field of the wrapper class for the `.proto` file, as described above; we have omitted the wrapper class name in the example. Extensions can be declared inside the scope of another type to prefix their generated symbol names. For example, a common pattern is to extend a message by a field *inside* the declaration of the field's type: ```proto message Baz { extend Foo { optional Baz foo_ext = 124; } } ``` In this case, an extension with identifier `foo_ext` and type `Baz` is declared inside the declaration of `Baz`, and referring to `foo_ext` requires the addition of a `Baz.` prefix: ```java Baz baz = createMyBaz(); Foo foo = Foo.newBuilder() .setExtension(Baz.fooExt, baz) .build(); assert foo.hasExtension(Baz.fooExt); assert foo.getExtension(Baz.fooExt) == baz; ``` When parsing a message that might have extensions, you must provide an [`ExtensionRegistry`](/reference/java/api-docs/com/google/protobuf/ExtensionRegistry.html) in which you have registered any extensions that you want to be able to parse. Otherwise, those extensions will be treated like unknown fields and the methods observing extensions will behave as if they don't exist. ```java ExtensionRegistry registry = ExtensionRegistry.newInstance(); registry.add(Baz.fooExt); Foo foo = Foo.parseFrom(input, registry); assert foo.hasExtension(Baz.fooExt); ``` ```java ExtensionRegistry registry = ExtensionRegistry.newInstance(); Foo foo = Foo.parseFrom(input, registry); assert foo.hasExtension(Baz.fooExt) == false; ``` ## Services {#service} If the `.proto` file contains the following line: ```proto option java_generic_services = true; ``` Then the protocol buffer compiler will generate code based on the service definitions found in the file as described in this section. However, the generated code may be undesirable as it is not tied to any particular RPC system, and thus requires more levels of indirection than code tailored to one system. If you do NOT want this code to be generated, add this line to the file: ```proto option java_generic_services = false; ``` If neither of the above lines are given, the option defaults to `false`, as generic services are deprecated. (Note that prior to 2.4.0, the option defaults to `true`) RPC systems based on `.proto`-language service definitions should provide [plugins](/reference/cpp/api-docs/google.protobuf.compiler.plugin.pb) to generate code appropriate for the system. These plugins are likely to require that abstract services are disabled, so that they can generate their own classes of the same names. Plugins are new in version 2.3.0 (January 2010). The remainder of this section describes what the protocol buffer compiler generates when abstract services are enabled. ### Interface {#interface} Given a service definition: ```proto service Foo { rpc Bar(FooRequest) returns(FooResponse); } ``` The protocol buffer compiler will generate an abstract class `Foo` to represent this service. `Foo` will have an abstract method for each method defined in the service definition. In this case, the method `Bar` is defined as: ```java abstract void bar(RpcController controller, FooRequest request, RpcCallback done); ``` The parameters are equivalent to the parameters of `Service.CallMethod()`, except that the `method` argument is implied and `request` and `done` specify their exact type. `Foo` subclasses the `Service` interface. The protocol buffer compiler automatically generates implementations of the methods of `Service` as follows: - `getDescriptorForType`: Returns the service's `ServiceDescriptor`. - `callMethod`: Determines which method is being called based on the provided method descriptor and calls it directly, down-casting the request message and callback to the correct types. - `getRequestPrototype` and `getResponsePrototype`: Returns the default instance of the request or response of the correct type for the given method. The following static method is also generated: - `static ServiceDescriptor getServiceDescriptor()`: Returns the type's descriptor, which contains information about what methods this service has and what their input and output types are. `Foo` will also contain a nested interface `Foo.Interface`. This is a pure interface that again contains methods corresponding to each method in your service definition. However, this interface does not extend the `Service` interface. This is a problem because RPC server implementations are usually written to use abstract `Service` objects, not your particular service. To solve this problem, if you have an object `impl` implementing `Foo.Interface`, you can call `Foo.newReflectiveService(impl)` to construct an instance of `Foo` that simply delegates to `impl`, and implements `Service`. To recap, when implementing your own service, you have two options: - Subclass `Foo` and implement its methods as appropriate, then hand instances of your subclass directly to the RPC server implementation. This is usually easiest, but some consider it less "pure". - Implement `Foo.Interface` and use `Foo.newReflectiveService(Foo.Interface)` to construct a `Service` wrapping it, then pass the wrapper to your RPC implementation. ### Stub {#stub} The protocol buffer compiler also generates a "stub" implementation of every service interface, which is used by clients wishing to send requests to servers implementing the service. For the `Foo` service (above), the stub implementation `Foo.Stub` will be defined as a nested class. `Foo.Stub` is a subclass of `Foo` which also implements the following methods: - `Foo.Stub(RpcChannel channel)`: Constructs a new stub which sends requests on the given channel. - `RpcChannel getChannel()`: Returns this stub's channel, as passed to the constructor. The stub additionally implements each of the service's methods as a wrapper around the channel. Calling one of the methods simply calls `channel.callMethod()`. The Protocol Buffer library does not include an RPC implementation. However, it includes all of the tools you need to hook up a generated service class to any arbitrary RPC implementation of your choice. You need only provide implementations of `RpcChannel` and `RpcController`. ### Blocking Interfaces {#blocking} The RPC classes described above all have non-blocking semantics: when you call a method, you provide a callback object which will be invoked once the method completes. Often it is easier (though possibly less scalable) to write code using blocking semantics, where the method simply doesn't return until it is done. To accommodate this, the protocol buffer compiler also generates blocking versions of your service class. `Foo.BlockingInterface` is equivalent to `Foo.Interface` except that each method simply returns the result rather than call a callback. So, for example, `bar` is defined as: ```java abstract FooResponse bar(RpcController controller, FooRequest request) throws ServiceException; ``` Analogous to non-blocking services, `Foo.newReflectiveBlockingService(Foo.BlockingInterface)` returns a `BlockingService` wrapping some `Foo.BlockingInterface`. Finally, `Foo.BlockingStub` returns a stub implementation of `Foo.BlockingInterface` that sends requests to a particular `BlockingRpcChannel`. ## Plugin Insertion Points {#plugins} [Code generator plugins](/reference/cpp/api-docs/google.protobuf.compiler.plugin.pb) that want to extend the output of the Java code generator may insert code of the following types using the given insertion point names. - `outer_class_scope`: Member declarations that belong in the file's wrapper class. - `class_scope:TYPENAME`: Member declarations that belong in a message class. `TYPENAME` is the full proto name, e.g. `package.MessageType`. - `builder_scope:TYPENAME`: Member declarations that belong in a message's builder class. `TYPENAME` is the full proto name, e.g. `package.MessageType`. - `enum_scope:TYPENAME`: Member declarations that belong in an enum class. `TYPENAME` is the full proto enum name, e.g. `package.EnumType`. - `message_implements:TYPENAME`: Class implementation declarations for a message class. `TYPENAME` is the full proto name, e.g. `package.MessageType`. - `builder_implements:TYPENAME`: Class implementation declarations for a builder class. `TYPENAME` is the full proto name, e.g. `package.MessageType`. Generated code cannot contain import statements, as these are prone to conflict with type names defined within the generated code itself. Instead, when referring to an external class, you must always use its fully-qualified name. The logic for determining output file names in the Java code generator is fairly complicated. You should probably look at the `protoc` source code, particularly `java_headers.cc`, to make sure you have covered all cases. Do not generate code which relies on private class members declared by the standard code generator, as these implementation details may change in future versions of Protocol Buffers. ## Utility Classes {#utility-classes} Protocol buffer provides [utility classes](/reference/java/api-docs/com/google/protobuf/util/package-summary.html) for message comparison, JSON conversion and working with [well-known types (predefined protocol buffer messages for common use-cases).](/reference/protobuf/google.protobuf)