This library is an implementation of MessagePack for TypeScript and JavaScript, providing a compact and efficient binary serialization format. Learn more about MessagePack at:
This library serves as a comprehensive reference implementation of MessagePack for JavaScript with a focus on accuracy, compatibility, interoperability, and performance.
Additionally, this is also a universal JavaScript library. It is compatible not only with browsers, but with Node.js or other JavaScript engines that implement ES2015+ standards. As it is written in TypeScript, this library bundles up-to-date type definition files (d.ts
).
*Note that this is the second edition of "MessagePack for JavaScript". The first edition, which was implemented in ES5 and never released to npmjs.com, is tagged as classic
.
import { deepStrictEqual } from "assert";
import { encode, decode } from "@msgpack/msgpack";
const object = {
nil: null,
integer: 1,
float: Math.PI,
string: "Hello, world!",
binary: Uint8Array.from([1, 2, 3]),
array: [10, 20, 30],
map: { foo: "bar" },
timestampExt: new Date(),
};
const encoded: Uint8Array = encode(object);
deepStrictEqual(decode(encoded), object);
- Synopsis
- Table of Contents
- Install
- API
encode(data: unknown, options?: EncoderOptions): Uint8Array
decode(buffer: ArrayLike<number> | BufferSource, options?: DecoderOptions): unknown
decodeMulti(buffer: ArrayLike<number> | BufferSource, options?: DecoderOptions): Generator<unknown, void, unknown>
decodeAsync(stream: ReadableStreamLike<ArrayLike<number> | BufferSource>, options?: DecoderOptions): Promise<unknown>
decodeArrayStream(stream: ReadableStreamLike<ArrayLike<number> | BufferSource>, options?: DecoderOptions): AsyncIterable<unknown>
decodeMultiStream(stream: ReadableStreamLike<ArrayLike<number> | BufferSource>, options?: DecoderOptions): AsyncIterable<unknown>
- Reusing Encoder and Decoder instances
- Extension Types
- Decoding a Blob
- MessagePack Specification
- Prerequisites
- Benchmark
- Distribution
- Deno Support
- Maintenance
- License
This library is published to npmjs.com
as @msgpack/msgpack.
npm install @msgpack/msgpack
It encodes data
into a single MessagePack-encoded object, and returns a byte array as Uint8Array
. It throws errors if data
is, or includes, a non-serializable object such as a function
or a symbol
.
for example:
import { encode } from "@msgpack/msgpack";
const encoded: Uint8Array = encode({ foo: "bar" });
console.log(encoded);
If you'd like to convert an uint8array
to a NodeJS Buffer
, use Buffer.from(arrayBuffer, offset, length)
in order not to copy the underlying ArrayBuffer
, while Buffer.from(uint8array)
copies it:
import { encode } from "@msgpack/msgpack";
const encoded: Uint8Array = encode({ foo: "bar" });
// `buffer` refers the same ArrayBuffer as `encoded`.
const buffer: Buffer = Buffer.from(encoded.buffer, encoded.byteOffset, encoded.byteLength);
console.log(buffer);
Name | Type | Default |
---|---|---|
extensionCodec | ExtensionCodec | ExtensionCodec.defaultCodec |
context | user-defined | - |
useBigInt64 | boolean | false |
maxDepth | number | 100 |
initialBufferSize | number | 2048 |
sortKeys | boolean | false |
forceFloat32 | boolean | false |
forceIntegerToFloat | boolean | false |
ignoreUndefined | boolean | false |
It decodes buffer
that includes a MessagePack-encoded object, and returns the decoded object typed unknown
.
buffer
must be an array of bytes, which is typically Uint8Array
or ArrayBuffer
. BufferSource
is defined as ArrayBuffer | ArrayBufferView
.
The buffer
must include a single encoded object. If the buffer
includes extra bytes after an object or the buffer
is empty, it throws RangeError
. To decode buffer
that includes multiple encoded objects, use decodeMulti()
or decodeMultiStream()
(recommended) instead.
for example:
import { decode } from "@msgpack/msgpack";
const encoded: Uint8Array;
const object = decode(encoded);
console.log(object);
NodeJS Buffer
is also acceptable because it is a subclass of Uint8Array
.
Name | Type | Default |
---|---|---|
extensionCodec | ExtensionCodec | ExtensionCodec.defaultCodec |
context | user-defined | - |
useBigInt64 | boolean | false |
maxStrLength | number | 4_294_967_295 (UINT32_MAX) |
maxBinLength | number | 4_294_967_295 (UINT32_MAX) |
maxArrayLength | number | 4_294_967_295 (UINT32_MAX) |
maxMapLength | number | 4_294_967_295 (UINT32_MAX) |
maxExtLength | number | 4_294_967_295 (UINT32_MAX) |
You can use max${Type}Length
to limit the length of each type decoded.
decodeMulti(buffer: ArrayLike<number> | BufferSource, options?: DecoderOptions): Generator<unknown, void, unknown>
It decodes buffer
that includes multiple MessagePack-encoded objects, and returns decoded objects as a generator. See also decodeMultiStream()
, which is an asynchronous variant of this function.
This function is not recommended to decode a MessagePack binary via I/O stream including sockets because it's synchronous. Instead, decodeMultiStream()
decodes a binary stream asynchronously, typically spending less CPU and memory.
for example:
import { decode } from "@msgpack/msgpack";
const encoded: Uint8Array;
for (const object of decodeMulti(encoded)) {
console.log(object);
}
decodeAsync(stream: ReadableStreamLike<ArrayLike<number> | BufferSource>, options?: DecoderOptions): Promise<unknown>
It decodes stream
, where ReadableStreamLike<T>
is defined as ReadableStream<T> | AsyncIterable<T>
, in an async iterable of byte arrays, and returns decoded object as unknown
type, wrapped in Promise
.
This function works asynchronously, and might CPU resources more efficiently compared with synchronous decode()
, because it doesn't wait for the completion of downloading.
This function is designed to work with whatwg fetch()
like this:
import { decodeAsync } from "@msgpack/msgpack";
const MSGPACK_TYPE = "application/x-msgpack";
const response = await fetch(url);
const contentType = response.headers.get("Content-Type");
if (contentType && contentType.startsWith(MSGPACK_TYPE) && response.body != null) {
const object = await decodeAsync(response.body);
// do something with object
} else { /* handle errors */ }
decodeArrayStream(stream: ReadableStreamLike<ArrayLike<number> | BufferSource>, options?: DecoderOptions): AsyncIterable<unknown>
It is alike to decodeAsync()
, but only accepts a stream
that includes an array of items, and emits a decoded item one by one.
for example:
import { decodeArrayStream } from "@msgpack/msgpack";
const stream: AsyncIterator<Uint8Array>;
// in an async function:
for await (const item of decodeArrayStream(stream)) {
console.log(item);
}
decodeMultiStream(stream: ReadableStreamLike<ArrayLike<number> | BufferSource>, options?: DecoderOptions): AsyncIterable<unknown>
It is alike to decodeAsync()
and decodeArrayStream()
, but the input stream
must consist of multiple MessagePack-encoded items. This is an asynchronous variant for decodeMulti()
.
In other words, it could decode an unlimited stream and emits a decoded item one by one.
for example:
import { decodeMultiStream } from "@msgpack/msgpack";
const stream: AsyncIterator<Uint8Array>;
// in an async function:
for await (const item of decodeMultiStream(stream)) {
console.log(item);
}
This function is available since v2.4.0; previously it was called as decodeStream()
.
Encoder
and Decoder
classes are provided to have better performance by reusing instances:
import { deepStrictEqual } from "assert";
import { Encoder, Decoder } from "@msgpack/msgpack";
const encoder = new Encoder();
const decoder = new Decoder();
const encoded: Uint8Array = encoder.encode(object);
deepStrictEqual(decoder.decode(encoded), object);
According to our benchmark, reusing Encoder
instance is about 20% faster
than encode()
function, and reusing Decoder
instance is about 2% faster
than decode()
function. Note that the result should vary in environments
and data structure.
Encoder
and Decoder
take the same options as encode()
and decode()
respectively.
To handle MessagePack Extension Types, this library provides ExtensionCodec
class.
This is an example to setup custom extension types that handles Map
and Set
classes in TypeScript:
import { encode, decode, ExtensionCodec } from "@msgpack/msgpack";
const extensionCodec = new ExtensionCodec();
// Set<T>
const SET_EXT_TYPE = 0 // Any in 0-127
extensionCodec.register({
type: SET_EXT_TYPE,
encode: (object: unknown): Uint8Array | null => {
if (object instanceof Set) {
return encode([...object], { extensionCodec });
} else {
return null;
}
},
decode: (data: Uint8Array) => {
const array = decode(data, { extensionCodec }) as Array<unknown>;
return new Set(array);
},
});
// Map<T>
const MAP_EXT_TYPE = 1; // Any in 0-127
extensionCodec.register({
type: MAP_EXT_TYPE,
encode: (object: unknown): Uint8Array => {
if (object instanceof Map) {
return encode([...object], { extensionCodec });
} else {
return null;
}
},
decode: (data: Uint8Array) => {
const array = decode(data, { extensionCodec }) as Array<[unknown, unknown]>;
return new Map(array);
},
});
const encoded = encode([new Set<any>(), new Map<any, any>()], { extensionCodec });
const decoded = decode(encoded, { extensionCodec });
Ensure you include your extensionCodec in any recursive encode and decode statements!
Note that extension types for custom objects must be [0, 127]
, while [-1, -128]
is reserved for MessagePack itself.
When you use an extension codec, it might be necessary to have encoding/decoding state to keep track of which objects got encoded/re-created. To do this, pass a context
to the EncoderOptions
and DecoderOptions
:
import { encode, decode, ExtensionCodec } from "@msgpack/msgpack";
class MyContext {
track(object: any) { /*...*/ }
}
class MyType { /* ... */ }
const extensionCodec = new ExtensionCodec<MyContext>();
// MyType
const MYTYPE_EXT_TYPE = 0 // Any in 0-127
extensionCodec.register({
type: MYTYPE_EXT_TYPE,
encode: (object, context) => {
if (object instanceof MyType) {
context.track(object); // <-- like this
return encode(object.toJSON(), { extensionCodec, context });
} else {
return null;
}
},
decode: (data, extType, context) => {
const decoded = decode(data, { extensionCodec, context });
const my = new MyType(decoded);
context.track(my); // <-- and like this
return my;
},
});
// and later
import { encode, decode } from "@msgpack/msgpack";
const context = new MyContext();
const encoded = = encode({myType: new MyType<any>()}, { extensionCodec, context });
const decoded = decode(encoded, { extensionCodec, context });
This library does not handle BigInt by default, but you have two options to handle it:
- Set
useBigInt64: true
to map bigint to MessagePack's int64/uint64 - Define a custom
ExtensionCodec
to map bigint to a MessagePack's extension type
useBigInt64: true
is the simplest way to handle bigint, but it has limitations:
- A bigint is encoded in 8 byte binaries even if it's a small integer
- A bigint must be smaller than the max value of the uint64 and larger than the min value of the int64. Otherwise the behavior is undefined.
So you might want to define a custom codec to handle bigint like this:
import { deepStrictEqual } from "assert";
import { encode, decode, ExtensionCodec } from "@msgpack/msgpack";
// to define a custom codec:
const BIGINT_EXT_TYPE = 0; // Any in 0-127
const extensionCodec = new ExtensionCodec();
extensionCodec.register({
type: BIGINT_EXT_TYPE,
encode(input: unknown): Uint8Array | null {
if (typeof input === "bigint") {
if (input <= Number.MAX_SAFE_INTEGER && input >= Number.MIN_SAFE_INTEGER) {
return encode(Number(input));
} else {
return encode(String(input));
}
} else {
return null;
}
},
decode(data: Uint8Array): bigint {
const val = decode(data);
if (!(typeof val === "string" || typeof val === "number")) {
throw new DecodeError(`unexpected BigInt source: ${val} (${typeof val})`);
}
return BigInt(val);
},
});
// to use it:
const value = BigInt(Number.MAX_SAFE_INTEGER) + BigInt(1);
const encoded: = encode(value, { extensionCodec });
deepStrictEqual(decode(encoded, { extensionCodec }), value);
There is a proposal for a new date/time representations in JavaScript:
This library maps Date
to the MessagePack timestamp extension by default, but you can re-map the temporal module (or Temporal Polyfill) to the timestamp extension like this:
import { Instant } from "@std-proposal/temporal";
import { deepStrictEqual } from "assert";
import {
encode,
decode,
ExtensionCodec,
EXT_TIMESTAMP,
encodeTimeSpecToTimestamp,
decodeTimestampToTimeSpec,
} from "@msgpack/msgpack";
// to define a custom codec
const extensionCodec = new ExtensionCodec();
extensionCodec.register({
type: EXT_TIMESTAMP, // override the default behavior!
encode(input: unknown): Uint8Array | null {
if (input instanceof Instant) {
const sec = input.seconds;
const nsec = Number(input.nanoseconds - BigInt(sec) * BigInt(1e9));
return encodeTimeSpecToTimestamp({ sec, nsec });
} else {
return null;
}
},
decode(data: Uint8Array): Instant {
const timeSpec = decodeTimestampToTimeSpec(data);
const sec = BigInt(timeSpec.sec);
const nsec = BigInt(timeSpec.nsec);
return Instant.fromEpochNanoseconds(sec * BigInt(1e9) + nsec);
},
});
// to use it
const instant = Instant.fromEpochMilliseconds(Date.now());
const encoded = encode(instant, { extensionCodec });
const decoded = decode(encoded, { extensionCodec });
deepStrictEqual(decoded, instant);
This will become default in this library with major-version increment, if the temporal module is standardized.
Blob
is a binary data container provided by browsers. To read its contents, you can use Blob#arrayBuffer()
or Blob#stream()
. Blob#stream()
is recommended if your target platform support it. This is because streaming
decode should be faster for large objects. In both ways, you need to use
asynchronous API.
async function decodeFromBlob(blob: Blob): unknown {
if (blob.stream) {
// Blob#stream(): ReadableStream<Uint8Array> (recommended)
return await decodeAsync(blob.stream());
} else {
// Blob#arrayBuffer(): Promise<ArrayBuffer> (if stream() is not available)
return decode(await blob.arrayBuffer());
}
}
This library is compatible with the "August 2017" revision of MessagePack specification at the point where timestamp ext was added:
- str/bin separation, added at August 2013
- extension types, added at August 2013
- timestamp ext type, added at August 2017
The living specification is here:
https://github.com/msgpack/msgpack
Note that as of June 2019 there're no official "version" on the MessagePack specification. See msgpack/msgpack#195 for the discussions.
The following table shows how JavaScript values are mapped to MessagePack formats and vice versa.
The mapping of integers varies on the setting of useBigInt64
.
The default, useBigInt64: false
is:
Source Value | MessagePack Format | Value Decoded |
---|---|---|
null, undefined | nil | null (*1) |
boolean (true, false) | bool family | boolean (true, false) |
number (53-bit int) | int family | number |
number (64-bit float) | float family | number |
string | str family | string |
ArrayBufferView | bin family | Uint8Array (*2) |
Array | array family | Array |
Object | map family | Object (*3) |
Date | timestamp ext family | Date (*4) |
bigint | N/A | N/A (*5) |
- *1 Both
null
andundefined
are mapped tonil
(0xC0
) type, and are decoded intonull
- *2 Any
ArrayBufferView
s including NodeJS'sBuffer
are mapped tobin
family, and are decoded intoUint8Array
- *3 In handling
Object
, it is regarded asRecord<string, unknown>
in terms of TypeScript - *4 MessagePack timestamps may have nanoseconds, which will lost when it is decoded into JavaScript
Date
. This behavior can be overridden by registering-1
for the extension codec. - *5 bigint is not supported in
useBigInt64: false
mode, but you can define an extension codec for it.
If you set useBigInt64: true
, the following mapping is used:
Source Value | MessagePack Format | Value Decoded |
---|---|---|
null, undefined | nil | null |
boolean (true, false) | bool family | boolean (true, false) |
number (32-bit int) | int family | number |
number (except for the above) | float family | number |
bigint | int64 / uint64 | bigint (*6) |
string | str family | string |
ArrayBufferView | bin family | Uint8Array |
Array | array family | Array |
Object | map family | Object |
Date | timestamp ext family | Date |
- *6 If the bigint is larger than the max value of uint64 or smaller than the min value of int64, then the behavior is undefined.
This is a universal JavaScript library that supports major browsers and NodeJS.
- ES2015 language features
- ES2018 standard library, including:
- Typed arrays (ES2015)
- Async iterations (ES2018)
- Features added in ES2015-ES2022
- whatwg encodings (
TextEncoder
andTextDecoder
)
ES2022 standard library used in this library can be polyfilled with core-js.
IE11 is no longer supported. If you'd like to use this library in IE11, use v2.x versions.
NodeJS v14 is required.
This module requires type definitions of AsyncIterator
, SourceBuffer
, whatwg streams, and so on. They are provided by "lib": ["ES2021", "DOM"]
in tsconfig.json
.
Regarding the TypeScript compiler version, only the latest TypeScript is tested in development.
Run-time performance is not the only reason to use MessagePack, but it's important to choose MessagePack libraries, so a benchmark suite is provided to monitor the performance of this library.
V8's built-in JSON has been improved for years, esp. JSON.parse()
is significantly improved in V8/7.6, it is the fastest deserializer as of 2019, as the benchmark result bellow suggests.
However, MessagePack can handles binary data effectively, actual performance depends on situations. You'd better take benchmark on your own use-case if performance matters.
Benchmark on NodeJS/v18.1.0 (V8/10.1)
operation | op | ms | op/s |
---|---|---|---|
buf = Buffer.from(JSON.stringify(obj)); | 902100 | 5000 | 180420 |
obj = JSON.parse(buf.toString("utf-8")); | 898700 | 5000 | 179740 |
buf = require("msgpack-lite").encode(obj); | 411000 | 5000 | 82200 |
obj = require("msgpack-lite").decode(buf); | 246200 | 5001 | 49230 |
buf = require("@msgpack/msgpack").encode(obj); | 843300 | 5000 | 168660 |
obj = require("@msgpack/msgpack").decode(buf); | 489300 | 5000 | 97860 |
buf = /* @msgpack/msgpack */ encoder.encode(obj); | 1154200 | 5000 | 230840 |
obj = /* @msgpack/msgpack */ decoder.decode(buf); | 448900 | 5000 | 89780 |
Note that JSON
cases use Buffer
to emulate I/O where a JavaScript string must be converted into a byte array encoded in UTF-8, whereas MessagePack modules deal with byte arrays.
The NPM package distributed in npmjs.com includes both ES2015+ and ES5 files:
dist/
is compiled into ES2019 with CommomJS, provided for NodeJS v10dist.es5+umd/
is compiled into ES5 with UMDdist.es5+umd/msgpack.min.js
- the minified filedist.es5+umd/msgpack.js
- the non-minified file
dist.es5+esm/
is compiled into ES5 with ES modules, provided for webpack-like bundlers and NodeJS's ESM-mode
If you use NodeJS and/or webpack, their module resolvers use the suitable one automatically.
This library is available via CDN:
<script crossorigin src="https://unpkg.com/@msgpack/msgpack"></script>
It loads MessagePack
module to the global object.
You can use this module on Deno.
See example/deno-*.ts
for examples.
deno.land/x
is not supported yet.
For simple testing:
npm run test
This library uses Travis CI.
test matrix:
- TypeScript targets
target=es2019
/target=es5
- JavaScript engines
- NodeJS, browsers (Chrome, Firefox, Safari, IE11, and so on)
See test:* in package.json and .travis.yml for details.
# run tests on NodeJS, Chrome, and Firefox
make test-all
# edit the changelog
code CHANGELOG.md
# bump version
npm version patch|minor|major
# run the publishing task
make publish
npm run update-dependencies
Copyright 2019 The MessagePack community.
This software uses the ISC license:
https://opensource.org/licenses/ISC
See LICENSE for details.