Pbandk is a Kotlin code generator and runtime for Protocol Buffers. It is built to work across multiple Kotlin platforms.
NOTE: This is the documentation for the version of pbandk currently in development. Documentation for the latest stable version is available at https://github.com/streem/pbandk/blob/v0.14.2/README.md.
Features
- Clean data class generation
- Works for JVM, Android, and JS (both legacy and IR), with experimental support for Native
- Support for proto2 and proto3 syntaxes
- JSON serialization/deserialization following the proto3 JSON spec (see streem#72 for some corner cases and Well-Known Types that are not handled yet)
- Oneof's are properly handled as sealed classes
- Specialized support to handle wrappers from the well-known types (e.g.
StringValue
,BoolValue
) as nullable primitives (String?
,Boolean?
, etc.) - JS platform leverages protobuf.js for best performance
- Support for custom service/gRPC code generator
- Support for custom options
Experimental
- Kotlin/Native support
Not Yet Implemented
- Specialized support for more of the well known types (e.g.
Any
) - Access to the protobuf descriptor from generated code
- Code comments on generated code
- Specialized support for the
deprecated
option
Read below for more information and see the examples.
This project is currently in beta. It has the core set of protobuf features implemented and is being used in production. But it is still under active development and new versions might introduce backwards-incompatible changes to support new features or to improve the library's usability in Kotlin. Pull requests are welcome for any of the "Not Yet Implemented" features above.
This project follows semantic versioning. After v1.0.0 is released (mid-2022 at the earliest), future versions will preserve backwards compatibility.
For the following addressbook.proto
file:
syntax = "proto3";
package tutorial;
import "google/protobuf/timestamp.proto";
message Person {
string name = 1;
int32 id = 2;
string email = 3;
enum PhoneType {
MOBILE = 0;
HOME = 1;
WORK = 2;
}
message PhoneNumber {
string number = 1;
PhoneType type = 2;
}
repeated PhoneNumber phones = 4;
google.protobuf.Timestamp last_updated = 5;
}
message AddressBook {
repeated Person people = 1;
}
The following file will be generated at tutorial/addressbook.kt
:
@file:OptIn(pbandk.PublicForGeneratedCode::class)
package tutorial
public data class Person(
val name: String = "",
val id: Int = 0,
val email: String = "",
val phones: List<tutorial.Person.PhoneNumber> = emptyList(),
val lastUpdated: pbandk.wkt.Timestamp? = null,
override val unknownFields: Map<Int, pbandk.UnknownField> = emptyMap()
) : pbandk.Message {
override operator fun plus(other: pbandk.Message?): Person = protoMergeImpl(other)
override val descriptor: pbandk.MessageDescriptor<Person> get() = Companion.descriptor
override val protoSize: Int by lazy { super.protoSize }
public companion object : pbandk.Message.Companion<Person> {
public val defaultInstance: Person by lazy { Person() }
override fun decodeWith(u: pbandk.MessageDecoder): Person = Person.decodeWithImpl(u)
override val descriptors: pbandk.MessageDescriptor<Person> by lazy {
val fieldsList = ArrayList<pbandk.FieldDescriptor<Person, *>>(5).apply {
add(
pbandk.FieldDescriptor(
messageDescriptor = this@Companion::descriptor,
name = "name",
number = 1,
type = pbandk.FieldDescriptor.Type.Primitive.String(),
jsonName = "name",
value = Person::name
)
)
add(
pbandk.FieldDescriptor(
messageDescriptor = this@Companion::descriptor,
name = "id",
number = 2,
type = pbandk.FieldDescriptor.Type.Primitive.Int32(),
jsonName = "id",
value = Person::id
)
)
add(
pbandk.FieldDescriptor(
messageDescriptor = this@Companion::descriptor,
name = "email",
number = 3,
type = pbandk.FieldDescriptor.Type.Primitive.String(),
jsonName = "email",
value = Person::email
)
)
add(
pbandk.FieldDescriptor(
messageDescriptor = this@Companion::descriptor,
name = "phones",
number = 4,
type = pbandk.FieldDescriptor.Type.Repeated<tutorial.Person.PhoneNumber>(valueType = pbandk.FieldDescriptor.Type.Message(messageCompanion = tutorial.Person.PhoneNumber.Companion)),
jsonName = "phones",
value = Person::phones
)
)
add(
pbandk.FieldDescriptor(
messageDescriptor = this@Companion::descriptor,
name = "last_updated",
number = 5,
type = pbandk.FieldDescriptor.Type.Message(messageCompanion = pbandk.wkt.Timestamp.Companion),
jsonName = "lastUpdated",
value = Person::lastUpdated
)
)
}
pbandk.MessageDescriptor(
fullName = "tutorial.Person",
messageClass = tutorial.Person::class,
messageCompanion = this,
fields = fieldsList
)
}
}
public sealed class PhoneType(override val value: Int, override val name: String? = null) : pbandk.Message.Enum {
override fun equals(other: kotlin.Any?): Boolean = other is Person.PhoneType && other.value == value
override fun hashCode(): Int = value.hashCode()
override fun toString(): String = "Person.PhoneType.${name ?: "UNRECOGNIZED"}(value=$value)"
public object MOBILE : PhoneType(0, "MOBILE")
public object HOME : PhoneType(1, "HOME")
public object WORK : PhoneType(2, "WORK")
public class UNRECOGNIZED(value: Int) : Person.PhoneType(value)
public companion object : pbandk.Message.Enum.Companion<Person.PhoneType> {
public val values: List<Person.PhoneType> by lazy { listOf(MOBILE, HOME, WORK) }
override fun fromValue(value: Int): Person.PhoneType = values.firstOrNull { it.value == value } ?: UNRECOGNIZED(value)
override fun fromName(name: String): Person.PhoneType = values.firstOrNull { it.name == name } ?: throw IllegalArgumentException("No PhoneType with name: $name")
}
}
public data class PhoneNumber(
val number: String = "",
val type: tutorial.Person.PhoneType = tutorial.Person.PhoneType.fromValue(0),
override val unknownFields: Map<Int, pbandk.UnknownField> = emptyMap()
) : pbandk.Message {
override operator fun plus(other: pbandk.Message?): Person.PhoneNumber = protoMergeImpl(other)
override val descriptor: MessageDescriptor<Person.PhoneNumber> get() = Companion.descriptor
override val protoSize: Int by lazy { super.protoSize }
public companion object : pbandk.Message.Companion<Person.PhoneNumber> {
public val defaultInstance: Person.PhoneNumber by lazy { Person.PhoneNumber() }
override fun decodeWith(u: pbandk.MessageDecoder): Person.PhoneNumber = Person.PhoneNumber.decodeWithImpl(u)
override val descriptor: pbandk.MessageDescriptor<PhoneNumber> by lazy {
val fieldsList = ArrayList<pbandk.FieldDescriptor<PhoneNumber, *>>(2).apply {
add(
pbandk.FieldDescriptor(
messageDescriptor = this@Companion::descriptor,
name = "number",
number = 1,
type = pbandk.FieldDescriptor.Type.Primitive.String(),
jsonName = "number",
value = PhoneNumber::number
)
)
add(
pbandk.FieldDescriptor(
messageDescriptor = this@Companion::descriptor,
name = "type",
number = 2,
type = pbandk.FieldDescriptor.Type.Enum(enumCompanion = tutorial.Person.PhoneType.Companion),
jsonName = "type",
value = PhoneNumber::type
)
)
}
pbandk.MessageDescriptor(
fullName = "tutorial.Person.PhoneNumber",
messageClass = tutorial.Person.PhoneNumber::class,
messageCompanion = this,
fields = fieldsList
)
}
}
}
}
public data class AddressBook(
val people: List<tutorial.Person> = emptyList(),
override val unknownFields: Map<Int, pbandk.UnknownField> = emptyMap()
) : pbandk.Message {
override operator fun plus(other: pbandk.Message?): AddressBook = protoMergeImpl(other)
override val descriptor: MessageDescriptor<AddressBook> get() = Companion.descriptor
override val protoSize: Int by lazy { super.protoSize }
public companion object : pbandk.Message.Companion<AddressBook> {
public val defaultInstance: AddressBook by lazy { AddressBook() }
override fun decodeWith(u: pbandk.MessageDecoder): AddressBook = AddressBook.decodeWithImpl(u)
override val descriptor: pbandk.MessageDescriptor<AddressBook> by lazy {
val fieldsList = ArrayList<pbandk.FieldDescriptor<AddressBook, *>>(1).apply {
add(
pbandk.FieldDescriptor(
messageDescriptor = this@Companion::descriptor,
name = "people",
number = 1,
type = pbandk.FieldDescriptor.Type.Repeated<tutorial.Person>(valueType = pbandk.FieldDescriptor.Type.Message(messageCompanion = tutorial.Person.Companion)),
jsonName = "people",
value = AddressBook::people
)
)
}
pbandk.MessageDescriptor(
fullName = "tutorial.AddressBook",
messageClass = tutorial.AddressBook::class,
messageCompanion = this,
fields = fieldsList
)
}
}
}
public fun Person?.orDefault(): Person = this ?: Person.defaultInstance
public fun Person.PhoneNumber?.orDefault(): Person.PhoneNumber = this ?: Person.PhoneNumber.defaultInstance
public fun AddressBook?.orDefault(): AddressBook = this ?: AddressBook.defaultInstance
// Omitted multiple supporting private extension methods
To see a full version of the file, see here. See the "Generated Code" section below under "Usage" for more details.
Pbandk's code generator leverages protoc
. Download the latest
protoc and make sure protoc
is on the PATH
.
Then download the latest released protoc-gen-pbandk self-executing jar
file (if you're using a SNAPSHOT build of pbandk, you might want to instead download the latest SNAPSHOT version of protoc-gen-pbandk-jvm-*-jvm8.jar),
rename it to protoc-gen-pbandk
, make the file executable (chmod +x protoc-gen-pbandk
), and make sure it is on the PATH
. To generate code from
sample.proto
and put the generated code in src/main/kotlin
, run:
protoc --pbandk_out=src/main/kotlin sample.proto
The file is generated as sample.kt
in the subdirectories specified by the package. Like other X_out
arguments,
comma-separated options can be added to --pbandk_out
before the colon and out dir path:
-
To explicitly set the Kotlin package to
my.pkg
, use thekotlin_package
option like so:protoc --pbandk_out=kotlin_package=my.pkg:src/main/kotlin sample.proto
-
If you have multiple proto packages, you can map them using
kotlin_package_mapping
option like so:protoc --pbandk_out=kotlin_package_mapping="simple.package->new.package;foo.bar.*->my.foo.bar.*":src/main/kotlin sample.proto
-
By default all generated classes have
public
visibility. To change the visibility tointernal
, use thevisibility
option like so:protoc --pbandk_out=visibility=internal:src/main/kotlin sample.proto
-
To log debug logs during generation,
log=debug
can be set as well.
Multiple options can be added to a single --pbandk_out
argument by separating them with commas.
In addition to running protoc
manually, the
Protobuf Plugin for Gradle can be used. See
this example to see how.
The self-executing jar file doesn't work on Windows. Also protoc
doesn't support finding
protoc-gen-pbandk.bat
on the PATH
. So it has to be specified explicitly as a plugin. Thus on
Windows you will first need to build protoc-gen-pbandk
locally:
./gradlew :protoc-gen-pbandk:protoc-gen-pbandk-jvm:installDist
And then provide the full path to protoc
:
protoc \
--pbandk_out=src/main/kotlin \
--plugin=protoc-gen-pbandk=/path/to/pbandk/protoc-gen-pbandk/jvm/build/install/protoc-gen-pbandk/bin/protoc-gen-pbandk.bat \
sample.proto
Pbandk's runtime library provides a Kotlin layer over the preferred Protobuf library for each platform. The libraries are present on Maven Central. Using Gradle:
repositories {
// This repository is only needed if using a SNAPSHOT version of pbandk
maven { url "https://s01.oss.sonatype.org/content/repositories/snapshots/" }
mavenCentral()
}
dependencies {
// Can be used from the `common` sourceset in a Kotlin Multiplatform project,
// or from platform-specific JVM, Android, JS, or Native sourcesets/projects.
implementation("pro.streem.pbandk:pbandk-runtime:0.14.3-SNAPSHOT")
}
Pbandk has a dependency on the preferred Protobuf library on each platform:
- Android: Google Protobuf Javalite library. The Android artifact supports SDK 21 or higher.
- JS: protobuf.js.
- JVM and Native: Pbandk uses its own pure-Kotlin protobuf implementation that is heavily based on the Google Protobuf Java library.
In addition, support for Kotlin's @OptIn
annotation
should be enabled in order to avoid compiler warnings in the generated code:
tasks.withType<KotlinCompile>().configureEach {
kotlinOptions.freeCompilerArgs += "-Xopt-in=kotlin.RequiresOptIn"
}
Pbandk does not generate gRPC code itself, but offers a pbandk.gen.ServiceGenerator
interface in
the protoc-gen-pbandk-lib-jvm
project with a single method that can be implemented to generate the
code.
To do this, first depend on the project but it will only be needed at compile time because it's already there at runtime:
dependencies {
compileOnly("pro.streem.pbandk:protoc-gen-pbandk-lib:0.14.3-SNAPSHOT")
}
Then, the kotlin_service_gen
option can be given to protoc
to use the generator. The option is a path-separated
collection of JAR files to put on the classpath. It can end with a pipe (i.e. |
) following by the fully-qualified
class name of the implementation of the ServiceGenerator
to use. If the last part is not present, it will use the
ServiceLoader
mechanism to find the first implementation to use. For example, to gen with my.Generator
from
gen.jar
, it might look like:
protoc --pbandk_out=kotlin_service_gen=gen.jar|my.Generator,kotlin_package=my.pkg:src/main/kotlin some.proto
For more details, see the custom-service-gen example.
The package is either the kotlin_package
plugin option, the java_package
protobuf option or the package set in the message. If the google.protobuf
package is referenced, it is assumed to be a well-known type and is changed to reference pbandk.wkt
.
Each Protobuf message extends pbandk.Message
and has an encodeToByteArray
method to encode the message with the
Protobuf binary encoding into a byte array. The companion object of every message has a decodeFromByteArray
method: it
accepts a byte array and returns an instance of the class. Each platform also provides additional encodeTo*
and
decodeFrom*
methods that are platform-specific. For example, the JVM provides encodeToStream
and decodeFromStream
methods that operate on Java's OutputStream
and InputStream
, respectively, and use
com.google.protobuf.CodedOutputStream
internally.
Messages are immutable Kotlin data classes. This means they automatically implement hashCode
, equals
, and
toString
. Each class has an unknownFields
map which contains information about extra fields the decoder didn't
recognize. If there are values in this map, they will be encoded on output. The MessageDecoder
instances have a
constructor option to discard unknown fields when reading.
For proto3, the only nullable fields are other messages and oneof fields. Other values have defaults. For proto2,
optional fields are nullable and defaulted as such. Types are basically the same as they would be in Java. However,
bytes
fields actually use a pbandk.ByteArr
class which is a simple wrapper around a byte array. This was done
because Kotlin does not handle array fields in data classes predictably and it wasn't worth overriding equals
and
hashCode
every time.
Regardless of optimize_for
options, the generated code is always the same. Each message has a protoSize
field that
lazily calculates the size of the message when first invoked. Also, each message has the plus
operator defined which
follows protobuf merge semantics.
Oneof fields are generated as nested classes of a common sealed base class. Each oneof inner field is a class that wraps a single value.
The parent message also contains a nullable field for every oneof inner field. This field resolves to the oneof inner field's value when the oneof is set to that inner field. Otherwise it resolves to null.
Enum fields are generated as sealed classes with a nested object
for each known enum value, and a
Unrecognized
nested class to hold unknown values. This is preferred over traditional enum classes
because enums in protobuf are open ended and may not be one of the specific known values. Traditional
enum classes would not be able to capture this state, and using sealed classes this way requires the
user to do explicit checks for the Unrecognized
value during exhaustive when clauses.
Each enum object contains a value
field with the numeric value of that enum, and a name
field
with the string value of that enum. Developers should use the fromValue
and fromName
methods
present on the companion object of the sealed class to map from a numeric or string value,
respectively, to the corresponding enum object.
The values
field on the companion object of the sealed class contains a list of all known enum
values.
Repeated fields are normal lists. Developers should make no assumptions about which list implementation is used. Maps are represented by Kotlin maps. In proto2, due to how map entries are serialized, both the key and the value are considered nullable.
Well known types (i.e. those in the google/protobuf
imports) are shipped with the runtime under the pbandk.wkt
package.
Specialized support is provided to map the types defined in google/protobuf/wrappers.proto
into Kotlin nullable primitives (e.g. String?
for google.protobuf.StringValue
, Int?
for google.protobuf.Int32Value
, etc.). Specialized support for other well-known types (e.g. using Kotlin Any
for google.protobuf.Any
) is not yet implemented.
Services can be handled with a custom service generator. See the "Service Code Generation" section above and the custom-service-gen example.
The project is built with Gradle and has several sub projects. In alphabetical order, they are:
conformance/js
- Conformance test runner for Kotlin/JSconformance/jvm
- Conformance test runner for Kotlin/JVMconformance/native
- Conformance test runner for Kotlin/Nativeconformance/lib
- Common multiplatform code for conformance testsprotoc-gen-pbandk/jvm
- Kotlin/JVM implementation of the code generator (can generate code for any platform, but requires JVM to run)protoc-gen-pbandk/lib
- Multiplatform code (only Kotlin/JVM supported at the moment) for the code generator andServiceGenerator
libraryruntime
- Multiplatform library for runtime Protobuf support
To generate the protoc-gen-pbandk
distribution, run:
./gradlew :protoc-gen-pbandk:protoc-gen-pbandk-jvm:assembleDist
If you want to make changes to pbandk
, and immediately test these changes in your separate project,
first install the generator locally:
./gradlew :protoc-gen-pbandk:protoc-gen-pbandk-jvm:installDist
This puts the files in the build/install
folder. Then you need to tell protoc
where to find this plugin file.
For example:
protoc \
--plugin=protoc-gen-pbandk=/path/to/pbandk/protoc-gen-pbandk/jvm/build/install/protoc-gen-pbandk/bin/protoc-gen-pbandk \
--pbandk_out=src/main/kotlin \
src/main/proto/*.proto
This will generate kotlin files for the specified *.proto
files, without needing to publish first.
To build the runtime library for both JS and the JVM, run:
./gradlew :pbandk-runtime:assemble
If any changes are made to the generated code that is output by protoc-gen-pbandk
, then the
well-known types (and other proto types used by pbandk) need to be re-generated using the updated
protoc-gen-pbandk
binary:
./gradlew generateProtos
Important: If making changes in both the :protoc-gen-pbandk:protoc-gen-pbandk-lib
and :pbandk-runtime
projects at
the same time, then it's likely the :pbandk-runtime:generateWellKnownTypeProtos
task will fail to compile. To work
around this, stash the changes in the :pbandk-runtime
project, run the generateWellKnownTypeProtos
task with only
the :protoc-gen-pbandk:protoc-gen-pbandk-lib
changes, and then unstash the :pbandk-runtime
changes and rerun the
generateWellKnownTypeProtos
task.
To run conformance tests, the conformance-test-runner must be built (does not work on Windows).
curl -sSLO https://github.com/protocolbuffers/protobuf/releases/download/v3.10.1/protobuf-all-3.10.1.tar.gz
tar xzvf protobuf-all-3.10.1.tar.gz
cd protobuf-3.10.1
./configure
make
cd conformance
make
You should now have a conformance-test-runner
available in this directory. Test it by running ./conformance-test-runner --help
Set the CONF_TEST_PATH
environment variable (used to run the tests below) with:
export CONF_TEST_PATH="$(pwd)/conformance-test-runner"
Now, back in pbandk
, build all JS. JVM and native projects via:
./gradlew :conformance:conformance-lib:assemble \
:conformance:conformance-jvm:installDist \
:conformance:conformance-native:build
You are now ready to run the conformance tests. Make sure CONF_TEST_PATH
environment variable is set to path/to/protobuf/conformance/conformance-test-runner
(see above).
Then, from the root directory:
./conformance/test-conformance.sh
Note that by default, the test-conformance.sh
script will run the conformance test for jvm
, js
and linux
. This will fail when running them on MacOS
due to missing linux binaries. So in that case, run the tests for each platform individually:
./conformance/test-conformance.sh jvm
./conformance/test-conformance.sh js
./conformance/test-conformance.sh macos
Releases are handled automatically via CI once the git tag is created.
Setup a couple shell variables to simplify the rest of the commands below:
export VERSION="0.9.0"
export NEXT_VERSION="0.9.1"
To create a new release:
- Update
CHANGELOG.md
: add a date for the release version, and update the release version's GitHub compare link with a tag instead ofHEAD
.- Note: if you are releasing a pre-release version (alpha, beta, rc) then you don't need to update
CHANGELOG.md
- Note: if you are releasing a pre-release version (alpha, beta, rc) then you don't need to update
- Update the pbandk version number in
gradle.properties
,README.md
, andexamples/*/build.gradle.kts
to remove theSNAPSHOT
suffix. For example, if the current version is0.9.0-SNAPSHOT
, then update it to be0.9.0
. - Comment out the note about the stable version of the documentation that is at the top of
README.md
and update it to point at the new version. - Commit the change. E.g.:
git commit -m "Bump to ${VERSION}" -a
. - Tag the new version. E.g.:
git tag -a -m "See https://github.com/streem/pbandk/blob/v${VERSION}/CHANGELOG.md" "v${VERSION}"
.
Then prepare the repository for development of the next version:
- Update
CHANGELOG.md
: add a section forNEXT_VERSION
that will follow the released version (e.g. if releasing0.9.0
then add a section for0.9.1
).- Note: if you are releasing a pre-release version (alpha, beta, rc) then you don't need to update
CHANGELOG.md
- Note: if you are releasing a pre-release version (alpha, beta, rc) then you don't need to update
- Update the pbandk version number in
gradle.properties
,README.md
, andexamples/*/build.gradle.kts
to${NEXT_VERSION}-SNAPSHOT
. For example,0.9.1-SNAPSHOT
. - Uncomment the note about the stable version of the documentation that is at the top of
README.md
. - Commit the change. E.g.:
git commit -m "Bump to ${NEXT_VERSION}-SNAPSHOT" -a
.
GitHub will build and publish the new release once it sees the new tag:
- Push the changes to GitHub:
git push origin --follow-tags master
. - Wait for CI to notice the new tag, build it, and upload it to Maven Central.
- Create a new release on GitHub. Use the contents of the tag description as the release description. E.g.:
gh release create "v${VERSION}" -F <(git tag -l --format='%(contents)' "v${VERSION}")
.
This repository was originally forked from https://github.com/cretz/pb-and-k. Many thanks to https://github.com/cretz for creating this library and building the initial feature set.