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Protocol Buffers are a language-neutral, platform-neutral, extensible way of serializing structured data for use in communications protocols, data storage, and more, originally designed at Google (see).
protobuf.js is a pure JavaScript implementation with TypeScript support for node.js and the browser. It’s easy to use, blazingly fast and works out of the box with .proto files!
Installation
How to include protobuf.js in your project.
Usage
A brief introduction to using the toolset.
Examples
A few examples to get you started.
Command line
How to use the command line utility.
Additional documentation
A list of available documentation resources.
Performance
A few internals and a benchmark on performance.
Compatibility
Notes on compatibility regarding browsers and optional libraries.
Building
How to build the library and its components yourself.
$> npm install protobufjs [--save --save-prefix=~]
var protobuf = require("protobufjs");
Note that this library’s versioning scheme is not semver-compatible for historical reasons. For guaranteed backward compatibility, always depend on ~6.A.B
instead of ^6.A.B
(hence the --save-prefix
above).
Development:
<script src="//cdn.rawgit.com/dcodeIO/protobuf.js/6.X.X/dist/protobuf.js"></script>
Production:
<script src="//cdn.rawgit.com/dcodeIO/protobuf.js/6.X.X/dist/protobuf.min.js"></script>
Remember to replace the version tag with the exact release your project depends upon.
The library supports CommonJS and AMD loaders and also exports globally as protobuf
.
Where bundle size is a factor, there are additional stripped-down versions of the full library (~19kb gzipped) available that exclude certain functionality:
var protobuf = require("protobufjs/light");
var protobuf = require("protobufjs/minimal");
Because JavaScript is a dynamically typed language, protobuf.js introduces the concept of a valid message in order to provide the best possible performance (and, as a side product, proper typings):
A valid message is an object (1) not missing any required fields and (2) exclusively composed of JS types understood by the wire format writer.
There are two possible types of valid messages and the encoder is able to work with both of these for convenience:
In a nutshell, the wire format writer understands the following types:
Field type | Expected JS type (create, encode) | Conversion (fromObject) |
---|---|---|
s-/u-/int32 s-/fixed32 |
number (32 bit integer) |
value | 0 if signedvalue >>> 0 if unsigned |
s-/u-/int64 s-/fixed64 |
Long -like (optimal)number (53 bit integer) |
Long.fromValue(value) with long.jsparseInt(value, 10) otherwise |
float double |
number |
Number(value) |
bool | boolean |
Boolean(value) |
string | string |
String(value) |
bytes | Uint8Array (optimal)Buffer (optimal under node)Array.<number> (8 bit integers) |
base64.decode(value) if a string Object with non-zero .length is assumed to be buffer-like |
enum | number (32 bit integer) |
Looks up the numeric id if a string |
message | Valid message | Message.fromObject(value) |
undefined
and null
are considered as not set if the field is optional.Array.<T>
.Object.<string,T>
with the key being the string representation of the respective value or an 8 characters long binary hash string for Long
-likes.With that in mind and again for performance reasons, each message class provides a distinct set of methods with each method doing just one thing. This avoids unnecessary assertions / redundant operations where performance is a concern but also forces a user to perform verification (of plain JavaScript objects that might just so happen to be a valid message) explicitly where necessary - for example when dealing with user input.
Note that Message
below refers to any message class.
Object
): null|string
var payload = "invalid (not an object)";
var err = AwesomeMessage.verify(payload);
if (err)
throw Error(err);
Message|Object
[, writer: Writer
]): Writer
var buffer = AwesomeMessage.encode(message).finish();
Message.encodeDelimited(message: Message|Object
[, writer: Writer
]): Writer
works like Message.encode
but additionally prepends the length of the message as a varint.
Message.decode(reader: Reader|Uint8Array
): Message
decodes a buffer to a message instance. If required fields are missing, it throws a util.ProtocolError
with an instance
property set to the so far decoded message. If the wire format is invalid, it throws an Error
.
try {
var decodedMessage = AwesomeMessage.decode(buffer);
} catch (e) {
if (e instanceof protobuf.util.ProtocolError) {
// e.instance holds the so far decoded message with missing required fields
} else {
// wire format is invalid
}
}
Message.decodeDelimited(reader: Reader|Uint8Array
): Message
works like Message.decode
but additionally reads the length of the message prepended as a varint.
Message.create(properties: Object
): Message
creates a new message instance from a set of properties that satisfy the requirements of a valid message. Where applicable, it is recommended to prefer Message.create
over Message.fromObject
because it doesn’t perform possibly redundant conversion.
var message = AwesomeMessage.create({ awesomeField: "AwesomeString" });
Object
): Message
var message = AwesomeMessage.fromObject({ awesomeField: 42 });
// converts awesomeField to a string
Message
[, options: ConversionOptions
]): Object
var object = AwesomeMessage.toObject(message, {
enums: String, // enums as string names
longs: String, // longs as strings (requires long.js)
bytes: String, // bytes as base64 encoded strings
defaults: true, // includes default values
arrays: true, // populates empty arrays (repeated fields) even if defaults=false
objects: true, // populates empty objects (map fields) even if defaults=false
oneofs: true // includes virtual oneof fields set to the present field's name
});
For reference, the following diagram aims to display relationships between the different methods and the concept of a valid message:
In other words:
verify
indicates that callingcreate
orencode
directly on the plain object will [result in a valid message respectively] succeed.fromObject
, on the other hand, does conversion from a broader range of plain objects to create valid messages. (ref)
It is possible to load existing .proto files using the full library, which parses and compiles the definitions to ready to use (reflection-based) message classes:
// awesome.proto
package awesomepackage;
syntax = "proto3";
message AwesomeMessage {
string awesome_field = 1; // becomes awesomeField
}
protobuf.load("awesome.proto", function(err, root) {
if (err)
throw err;
// Obtain a message type
var AwesomeMessage = root.lookupType("awesomepackage.AwesomeMessage");
// Exemplary payload
var payload = { awesomeField: "AwesomeString" };
// Verify the payload if necessary (i.e. when possibly incomplete or invalid)
var errMsg = AwesomeMessage.verify(payload);
if (errMsg)
throw Error(errMsg);
// Create a new message
var message = AwesomeMessage.create(payload); // or use .fromObject if conversion is necessary
// Encode a message to an Uint8Array (browser) or Buffer (node)
var buffer = AwesomeMessage.encode(message).finish();
// ... do something with buffer
// Decode an Uint8Array (browser) or Buffer (node) to a message
var message = AwesomeMessage.decode(buffer);
// ... do something with message
// If the application uses length-delimited buffers, there is also encodeDelimited and decodeDelimited.
// Maybe convert the message back to a plain object
var object = AwesomeMessage.toObject(message, {
longs: String,
enums: String,
bytes: String,
// see ConversionOptions
});
});
Additionally, promise syntax can be used by omitting the callback, if preferred:
protobuf.load("awesome.proto")
.then(function(root) {
...
});
The library utilizes JSON descriptors that are equivalent to a .proto definition. For example, the following is identical to the .proto definition seen above:
// awesome.json
{
"nested": {
"awesomepackage": {
"nested": {
"AwesomeMessage": {
"fields": {
"awesomeField": {
"type": "string",
"id": 1
}
}
}
}
}
}
}
JSON descriptors closely resemble the internal reflection structure:
Type (T) | Extends | Type-specific properties |
---|---|---|
ReflectionObject | options | |
Namespace | ReflectionObject | nested |
Root | Namespace | nested |
Type | Namespace | fields |
Enum | ReflectionObject | values |
Field | ReflectionObject | rule, type, id |
MapField | Field | keyType |
OneOf | ReflectionObject | oneof (array of field names) |
Service | Namespace | methods |
Method | ReflectionObject | type, requestType, responseType, requestStream, responseStream |
T.fromJSON(name, json)
creates the respective reflection object from a JSON descriptorT#toJSON()
creates a JSON descriptor from the respective reflection object (its name is used as the key within the parent)Exclusively using JSON descriptors instead of .proto files enables the use of just the light library (the parser isn’t required in this case).
A JSON descriptor can either be loaded the usual way:
protobuf.load("awesome.json", function(err, root) {
if (err) throw err;
// Continue at "Obtain a message type" above
});
Or it can be loaded inline:
var jsonDescriptor = require("./awesome.json"); // exemplary for node
var root = protobuf.Root.fromJSON(jsonDescriptor);
// Continue at "Obtain a message type" above
Both the full and the light library include full reflection support. One could, for example, define the .proto definitions seen in the examples above using just reflection:
...
var Root = protobuf.Root,
Type = protobuf.Type,
Field = protobuf.Field;
var AwesomeMessage = new Type("AwesomeMessage").add(new Field("awesomeField", 1, "string"));
var root = new Root().define("awesomepackage").add(AwesomeMessage);
// Continue at "Create a new message" above
...
Detailed information on the reflection structure is available within the API documentation.
Message classes can also be extended with custom functionality and it is also possible to register a custom constructor with a reflected message type:
...
// Define a custom constructor
function AwesomeMessage(properties) {
// custom initialization code
...
}
// Register the custom constructor with its reflected type (*)
root.lookupType("awesomepackage.AwesomeMessage").ctor = AwesomeMessage;
// Define custom functionality
AwesomeMessage.customStaticMethod = function() { ... };
AwesomeMessage.prototype.customInstanceMethod = function() { ... };
// Continue at "Create a new message" above
(*) Besides referencing its reflected type through AwesomeMessage.$type
and AwesomeMesage#$type
, the respective custom class is automatically populated with:
AwesomeMessage.create
AwesomeMessage.encode
and AwesomeMessage.encodeDelimited
AwesomeMessage.decode
and AwesomeMessage.decodeDelimited
AwesomeMessage.verify
AwesomeMessage.fromObject
, AwesomeMessage.toObject
and AwesomeMessage#toJSON
Afterwards, decoded messages of this type are instanceof AwesomeMessage
.
Alternatively, it is also possible to reuse and extend the internal constructor if custom initialization code is not required:
...
// Reuse the internal constructor
var AwesomeMessage = root.lookupType("awesomepackage.AwesomeMessage").ctor;
// Define custom functionality
AwesomeMessage.customStaticMethod = function() { ... };
AwesomeMessage.prototype.customInstanceMethod = function() { ... };
// Continue at "Create a new message" above
The library also supports consuming services but it doesn’t make any assumptions about the actual transport channel. Instead, a user must provide a suitable RPC implementation, which is an asynchronous function that takes the reflected service method, the binary request and a node-style callback as its parameters:
function rpcImpl(method, requestData, callback) {
// perform the request using an HTTP request or a WebSocket for example
var responseData = ...;
// and call the callback with the binary response afterwards:
callback(null, responseData);
}
Below is a working example with a typescript implementation using grpc npm package.
const grpc = require('grpc')
const Client = grpc.makeGenericClientConstructor({})
const client = new Client(
grpcServerUrl,
grpc.credentials.createInsecure()
)
const rpcImpl = function(method, requestData, callback) {
client.makeUnaryRequest(
method.name,
arg => arg,
arg => arg,
requestData,
callback
)
}
Example:
// greeter.proto
syntax = "proto3";
service Greeter {
rpc SayHello (HelloRequest) returns (HelloReply) {}
}
message HelloRequest {
string name = 1;
}
message HelloReply {
string message = 1;
}
...
var Greeter = root.lookup("Greeter");
var greeter = Greeter.create(/* see above */ rpcImpl, /* request delimited? */ false, /* response delimited? */ false);
greeter.sayHello({ name: 'you' }, function(err, response) {
console.log('Greeting:', response.message);
});
Services also support promises:
greeter.sayHello({ name: 'you' })
.then(function(response) {
console.log('Greeting:', response.message);
});
There is also an example for streaming RPC.
Note that the service API is meant for clients. Implementing a server-side endpoint pretty much always requires transport channel (i.e. http, websocket, etc.) specific code with the only common denominator being that it decodes and encodes messages.
The library ships with its own type definitions and modern editors like Visual Studio Code will automatically detect and use them for code completion.
The npm package depends on @types/node because of Buffer
and @types/long because of Long
. If you are not building for node and/or not using long.js, it should be safe to exclude them manually.
The API shown above works pretty much the same with TypeScript. However, because everything is typed, accessing fields on instances of dynamically generated message classes requires either using bracket-notation (i.e. message["awesomeField"]
) or explicit casts. Alternatively, it is possible to use a typings file generated for its static counterpart.
import { load } from "protobufjs"; // respectively "./node_modules/protobufjs"
load("awesome.proto", function(err, root) {
if (err)
throw err;
// example code
const AwesomeMessage = root.lookupType("awesomepackage.AwesomeMessage");
let message = AwesomeMessage.create({ awesomeField: "hello" });
console.log(`message = ${JSON.stringify(message)}`);
let buffer = AwesomeMessage.encode(message).finish();
console.log(`buffer = ${Array.prototype.toString.call(buffer)}`);
let decoded = AwesomeMessage.decode(buffer);
console.log(`decoded = ${JSON.stringify(decoded)}`);
});
If you generated static code to bundle.js
using the CLI and its type definitions to bundle.d.ts
, then you can just do:
import { AwesomeMessage } from "./bundle.js";
// example code
let message = AwesomeMessage.create({ awesomeField: "hello" });
let buffer = AwesomeMessage.encode(message).finish();
let decoded = AwesomeMessage.decode(buffer);
The library also includes an early implementation of decorators.
Note that decorators are an experimental feature in TypeScript and that declaration order is important depending on the JS target. For example, @Field.d(2, AwesomeArrayMessage)
requires that AwesomeArrayMessage
has been defined earlier when targeting ES5
.
import { Message, Type, Field, OneOf } from "protobufjs/light"; // respectively "./node_modules/protobufjs/light.js"
export class AwesomeSubMessage extends Message<AwesomeSubMessage> {
@Field.d(1, "string")
public awesomeString: string;
}
export enum AwesomeEnum {
ONE = 1,
TWO = 2
}
@Type.d("SuperAwesomeMessage")
export class AwesomeMessage extends Message<AwesomeMessage> {
@Field.d(1, "string", "optional", "awesome default string")
public awesomeField: string;
@Field.d(2, AwesomeSubMessage)
public awesomeSubMessage: AwesomeSubMessage;
@Field.d(3, AwesomeEnum, "optional", AwesomeEnum.ONE)
public awesomeEnum: AwesomeEnum;
@OneOf.d("awesomeSubMessage", "awesomeEnum")
public which: string;
}
// example code
let message = new AwesomeMessage({ awesomeField: "hello" });
let buffer = AwesomeMessage.encode(message).finish();
let decoded = AwesomeMessage.decode(buffer);
Supported decorators are:
Type.d(typeName?: string
) (optional)
annotates a class as a protobuf message type. If typeName
is not specified, the constructor’s runtime function name is used for the reflected type.
Field.d<T>(fieldId: number
, fieldType: string | Constructor<T>
, fieldRule?: "optional" | "required" | "repeated"
, defaultValue?: T
)
annotates a property as a protobuf field with the specified id and protobuf type.
MapField.d<T extends { [key: string]: any }>(fieldId: number
, fieldKeyType: string
, fieldValueType. string | Constructor<{}>
)
annotates a property as a protobuf map field with the specified id, protobuf key and value type.
OneOf.d<T extends string>(…fieldNames: string[]
)
annotates a property as a protobuf oneof covering the specified fields.
Other notes:
protobuf.roots["decorated"]
using a flat structure, so no duplicate names.ProTip! Not as pretty, but you can use decorators in plain JavaScript as well.
Note that moving the CLI to its own package is a work in progress. At the moment, it’s still part of the main package.
The command line interface (CLI) can be used to translate between file formats and to generate static code as well as TypeScript definitions.
Translates between file formats and generates static code.
-t, --target Specifies the target format. Also accepts a path to require a custom target.
json JSON representation
json-module JSON representation as a module
proto2 Protocol Buffers, Version 2
proto3 Protocol Buffers, Version 3
static Static code without reflection (non-functional on its own)
static-module Static code without reflection as a module
-p, --path Adds a directory to the include path.
-o, --out Saves to a file instead of writing to stdout.
--sparse Exports only those types referenced from a main file (experimental).
Module targets only:
-w, --wrap Specifies the wrapper to use. Also accepts a path to require a custom wrapper.
default Default wrapper supporting both CommonJS and AMD
commonjs CommonJS wrapper
amd AMD wrapper
es6 ES6 wrapper (implies --es6)
closure A closure adding to protobuf.roots where protobuf is a global
-r, --root Specifies an alternative protobuf.roots name.
-l, --lint Linter configuration. Defaults to protobuf.js-compatible rules:
eslint-disable block-scoped-var, no-redeclare, no-control-regex, no-prototype-builtins
--es6 Enables ES6 syntax (const/let instead of var)
Proto sources only:
--keep-case Keeps field casing instead of converting to camel case.
Static targets only:
--no-create Does not generate create functions used for reflection compatibility.
--no-encode Does not generate encode functions.
--no-decode Does not generate decode functions.
--no-verify Does not generate verify functions.
--no-convert Does not generate convert functions like from/toObject
--no-delimited Does not generate delimited encode/decode functions.
--no-beautify Does not beautify generated code.
--no-comments Does not output any JSDoc comments.
--force-long Enforces the use of 'Long' for s-/u-/int64 and s-/fixed64 fields.
--force-number Enforces the use of 'number' for s-/u-/int64 and s-/fixed64 fields.
--force-message Enforces the use of message instances instead of plain objects.
usage: pbjs [options] file1.proto file2.json ... (or pipe) other | pbjs [options] -
For production environments it is recommended to bundle all your .proto files to a single .json file, which minimizes the number of network requests and avoids any parser overhead (hint: works with just the light library):
$> pbjs -t json file1.proto file2.proto > bundle.json
Now, either include this file in your final bundle:
var root = protobuf.Root.fromJSON(require("./bundle.json"));
or load it the usual way:
protobuf.load("bundle.json", function(err, root) {
...
});
Generated static code, on the other hand, works with just the minimal library. For example
$> pbjs -t static-module -w commonjs -o compiled.js file1.proto file2.proto
will generate static code for definitions within file1.proto
and file2.proto
to a CommonJS module compiled.js
.
ProTip! Documenting your .proto files with /** ... */
-blocks or (trailing) /// ...
lines translates to generated static code.
Generates TypeScript definitions from annotated JavaScript files.
-o, --out Saves to a file instead of writing to stdout.
-g, --global Name of the global object in browser environments, if any.
--no-comments Does not output any JSDoc comments.
Internal flags:
-n, --name Wraps everything in a module of the specified name.
-m, --main Whether building the main library without any imports.
usage: pbts [options] file1.js file2.js ... (or) other | pbts [options] -
Picking up on the example above, the following not only generates static code to a CommonJS module compiled.js
but also its respective TypeScript definitions to compiled.d.ts
:
$> pbjs -t static-module -w commonjs -o compiled.js file1.proto file2.proto
$> pbts -o compiled.d.ts compiled.js
Additionally, TypeScript definitions of static modules are compatible with their reflection-based counterparts (i.e. as exported by JSON modules), as long as the following conditions are met:
new SomeMessage(...)
, always use SomeMessage.create(...)
because reflection objects do not provide a constructor.MyMessage.MyEnum
instead of root.lookup("MyMessage.MyEnum")
).For example, the following generates a JSON module bundle.js
and a bundle.d.ts
, but no static code:
$> pbjs -t json-module -w commonjs -o bundle.js file1.proto file2.proto
$> pbjs -t static-module file1.proto file2.proto | pbts -o bundle.d.ts -
While using .proto files directly requires the full library respectively pure reflection/JSON the light library, pretty much all code but the relatively short descriptors is shared.
Static code, on the other hand, requires just the minimal library, but generates additional source code without any reflection features. This also implies that there is a break-even point where statically generated code becomes larger than descriptor-based code once the amount of code generated exceeds the size of the full respectively light library.
There is no significant difference performance-wise as the code generated statically is pretty much the same as generated at runtime and both are largely interchangeable as seen in the previous section.
Source | Library | Advantages | Tradeoffs |
---|---|---|---|
.proto | full | Easily editable Interoperability with other libraries No compile step |
Some parsing and possibly network overhead |
JSON | light | Easily editable No parsing overhead Single bundle (no network overhead) |
protobuf.js specific Has a compile step |
static | minimal | Works where eval access is restrictedFully documented Small footprint for small protos |
Can be hard to edit No reflection Has a compile step |
Both utilities can be used programmatically by providing command line arguments and a callback to their respective main
functions:
var pbjs = require("protobufjs/cli/pbjs"); // or require("protobufjs/cli").pbjs / .pbts
pbjs.main([ "--target", "json-module", "path/to/myproto.proto" ], function(err, output) {
if (err)
throw err;
// do something with output
});
The package includes a benchmark that compares protobuf.js performance to native JSON (as far as this is possible) and Google’s JS implementation. On an i7-2600K running node 6.9.1 it yields:
benchmarking encoding performance ...
protobuf.js (reflect) x 541,707 ops/sec ±1.13% (87 runs sampled)
protobuf.js (static) x 548,134 ops/sec ±1.38% (89 runs sampled)
JSON (string) x 318,076 ops/sec ±0.63% (93 runs sampled)
JSON (buffer) x 179,165 ops/sec ±2.26% (91 runs sampled)
google-protobuf x 74,406 ops/sec ±0.85% (86 runs sampled)
protobuf.js (static) was fastest
protobuf.js (reflect) was 0.9% ops/sec slower (factor 1.0)
JSON (string) was 41.5% ops/sec slower (factor 1.7)
JSON (buffer) was 67.6% ops/sec slower (factor 3.1)
google-protobuf was 86.4% ops/sec slower (factor 7.3)
benchmarking decoding performance ...
protobuf.js (reflect) x 1,383,981 ops/sec ±0.88% (93 runs sampled)
protobuf.js (static) x 1,378,925 ops/sec ±0.81% (93 runs sampled)
JSON (string) x 302,444 ops/sec ±0.81% (93 runs sampled)
JSON (buffer) x 264,882 ops/sec ±0.81% (93 runs sampled)
google-protobuf x 179,180 ops/sec ±0.64% (94 runs sampled)
protobuf.js (reflect) was fastest
protobuf.js (static) was 0.3% ops/sec slower (factor 1.0)
JSON (string) was 78.1% ops/sec slower (factor 4.6)
JSON (buffer) was 80.8% ops/sec slower (factor 5.2)
google-protobuf was 87.0% ops/sec slower (factor 7.7)
benchmarking combined performance ...
protobuf.js (reflect) x 275,900 ops/sec ±0.78% (90 runs sampled)
protobuf.js (static) x 290,096 ops/sec ±0.96% (90 runs sampled)
JSON (string) x 129,381 ops/sec ±0.77% (90 runs sampled)
JSON (buffer) x 91,051 ops/sec ±0.94% (90 runs sampled)
google-protobuf x 42,050 ops/sec ±0.85% (91 runs sampled)
protobuf.js (static) was fastest
protobuf.js (reflect) was 4.7% ops/sec slower (factor 1.0)
JSON (string) was 55.3% ops/sec slower (factor 2.2)
JSON (buffer) was 68.6% ops/sec slower (factor 3.2)
google-protobuf was 85.5% ops/sec slower (factor 6.9)
These results are achieved by
You can also run the benchmark …
$> npm run bench
and the profiler yourself (the latter requires a recent version of node):
$> npm run prof <encode|decode|encode-browser|decode-browser> [iterations=10000000]
Note that as of this writing, the benchmark suite performs significantly slower on node 7.2.0 compared to 6.9.1 because moths.
google/protobuf/descriptor.proto
, options are parsed and presented literally.Long
instance instead of a possibly unsafe JavaScript number (see).To build the library or its components yourself, clone it from GitHub and install the development dependencies:
$> git clone https://github.com/dcodeIO/protobuf.js.git
$> cd protobuf.js
$> npm install
Building the respective development and production versions with their respective source maps to dist/
:
$> npm run build
Building the documentation to docs/
:
$> npm run docs
Building the TypeScript definition to index.d.ts
:
$> npm run types
By default, protobuf.js integrates into any browserify build-process without requiring any optional modules. Hence:
long
module somewhere in your project as it will be excluded otherwise. This assumes that a global require
function is present that protobuf.js can call to obtain the long module.If there is no global require
function present after bundling, it’s also possible to assign the long module programmatically:
var Long = ...;
protobuf.util.Long = Long;
protobuf.configure();
License: BSD 3-Clause License