Released under the terms of the MIT LICENSE.
Should I use this in production?
If you are thinking of using the master branch of this library in production, stop.
Master is not stable; it is our development branch, and only tagged releases may be classified as stable.
Can I trust this code?
Don't trust. Verify.
We recommend every user of this library and the bitcoinjs ecosystem audit and verify any underlying code for its validity and suitability, including reviewing any and all of your project's dependencies.
Mistakes and bugs happen, but with your help in resolving and reporting issues, together we can produce open source software that is:
- Easy to audit and verify,
- Tested, with test coverage >95%,
- Advanced and feature rich,
- Standardized, using prettier and Node
Buffer's throughout, and
- Friendly, with a strong and helpful community, ready to answer questions.
Presently, we do not have any formal documentation other than our examples, please ask for help if our examples aren't enough to guide you.
You can find a Web UI that covers most of the
p2*.ts APIs here.
npm install bitcoinjs-lib
Typically we support the Node Maintenance LTS version.
If in doubt, see the .travis.yml for what versions are used by our continuous integration tests.
WARNING: We presently don't provide any tooling to verify that the release on
npm matches GitHub. As such, you should verify anything downloaded by
npm against your own verified copy.
Crypto is hard.
When working with private keys, the random number generator is fundamentally one of the most important parts of any software you write.
For random number generation, we default to the
randombytes module, which uses
window.crypto.getRandomValues in the browser, or Node js'
crypto.randomBytes, depending on your build system.
Although this default is ~OK, there is no simple way to detect if the underlying RNG provided is good enough, or if it is catastrophically bad.
You should always verify this yourself to your own standards.
This library uses tiny-secp256k1, which uses RFC6979 to help prevent
k re-use and exploitation.
Unfortunately, this isn't a silver bullet.
Buffer (UInt8Array), for example, can trivially result in catastrophic fund loss without any warning.
It can do this through undermining your random number generation, accidentally producing a duplicate
k value, sending Bitcoin to a malformed output script, or any of a million different ways.
Running tests in your target environment is important and a recommended step to verify continuously.
Finally, adhere to best practice.
We are not an authorative source of best practice, but, at the very least:
The recommended method of using
bitcoinjs-lib in your browser is through Browserify.
If you're familiar with how to use browserify, ignore this and carry on, otherwise, it is recommended to read the tutorial at https://browserify.org/.
NOTE: We use Node Maintenance LTS features, if you need strict ES5, use
--transform babelify in conjunction with your
browserify step (using an
WARNING: iOS devices have problems, use atleast [email protected] or greater, and enforce the test suites (for
Buffer, and any other dependency) pass before use.
Typescript or VSCode users
Type declarations for Typescript are included in this library. Normal installation should include all the needed type information.
The below examples are implemented as integration tests, they should be very easy to understand.
Otherwise, pull requests are appreciated.
Some examples interact (via HTTPS) with a 3rd Party Blockchain Provider (3PBP).
- Generate a random address
- Import an address via WIF
- Generate a 2-of-3 P2SH multisig address
- Generate a SegWit address
- Generate a SegWit P2SH address
- Generate a SegWit 3-of-4 multisig address
- Generate a SegWit 2-of-2 P2SH multisig address
- Support the retrieval of transactions for an address (3rd party blockchain)
- Generate a Testnet address
- Generate a Litecoin address
- Create a 1-to-1 Transaction
- Create (and broadcast via 3PBP) a typical Transaction
- Create (and broadcast via 3PBP) a Transaction with an OP_RETURN output
- Create (and broadcast via 3PBP) a Transaction with a 2-of-4 P2SH(multisig) input
- Create (and broadcast via 3PBP) a Transaction with a SegWit P2SH(P2WPKH) input
- Create (and broadcast via 3PBP) a Transaction with a SegWit P2WPKH input
- Create (and broadcast via 3PBP) a Transaction with a SegWit P2PK input
- Create (and broadcast via 3PBP) a Transaction with a SegWit 3-of-4 P2SH(P2WSH(multisig)) input
- Create (and broadcast via 3PBP) a Transaction and sign with an HDSigner interface (bip32)
- Import a BIP32 testnet xpriv and export to WIF
- Export a BIP32 xpriv, then import it
- Export a BIP32 xpub
- Create a BIP32, bitcoin, account 0, external address
- Create a BIP44, bitcoin, account 0, external address
- Create a BIP49, bitcoin testnet, account 0, external address
- Use BIP39 to generate BIP32 addresses
- Create (and broadcast via 3PBP) a Transaction where Alice can redeem the output after the expiry (in the past)
- Create (and broadcast via 3PBP) a Transaction where Alice can redeem the output after the expiry (in the future)
- Create (and broadcast via 3PBP) a Transaction where Alice and Bob can redeem the output at any time
- Create (but fail to broadcast via 3PBP) a Transaction where Alice attempts to redeem before the expiry
- Create (and broadcast via 3PBP) a Transaction where Alice can redeem the output after the expiry (in the future) (simple CHECKSEQUENCEVERIFY)
- Create (but fail to broadcast via 3PBP) a Transaction where Alice attempts to redeem before the expiry (simple CHECKSEQUENCEVERIFY)
- Create (and broadcast via 3PBP) a Transaction where Bob and Charles can send (complex CHECKSEQUENCEVERIFY)
- Create (and broadcast via 3PBP) a Transaction where Alice (mediator) and Bob can send after 2 blocks (complex CHECKSEQUENCEVERIFY)
- Create (and broadcast via 3PBP) a Transaction where Alice (mediator) can send after 5 blocks (complex CHECKSEQUENCEVERIFY)
If you have a use case that you feel could be listed here, please ask for it!
Running the test suite
npm run-script coverage
BIP21 - A BIP21 compatible URL encoding library
BIP38 - Passphrase-protected private keys
BIP39 - Mnemonic generation for deterministic keys
BIP32-Utils - A set of utilities for working with BIP32
BIP66 - Strict DER signature decoding
BIP68 - Relative lock-time encoding library
BIP69 - Lexicographical Indexing of Transaction Inputs and Outputs
Base58 - Base58 encoding/decoding
Base58 Check - Base58 check encoding/decoding
Bech32 - A BIP173/BIP350 compliant Bech32/Bech32m encoding library
coinselect - A fee-optimizing, transaction input selection module for bitcoinjs-lib.
merkle-lib - A performance conscious library for merkle root and tree calculations.
minimaldata - A module to check bitcoin policy: SCRIPTVERIFYMINIMALDATA