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@neon-exchange/nash-protocol

TypeScript implementation of Nash crypto routines

  • 2.1.22
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  • npm
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nash-protocol

Implementation of Nash cryptographic routines

This document is very WIP and should be checked for accuracy by someone with more expertise!

Getting started

yarn install
yarn build
yarn test

API

/*
  Secure-randomly generates a series of random bytes.
  * publicKey is used to verify signatures.
  * secretKey is the "master key" used to sign stuff and to generate mnemonic.

  Uses crypto-browserify/randombytes which polyfills node crypto.

  Spec: SIGGEN()
 */
getEntropy = () => { publicKey: Buffer, secretKey: Buffer }

/*
  Converts entropy to wordlist. We can supply our own wordlist for i18n.
  This is not an encryption, it's a simple mapping.

  Uses bitcoinjs/bip39 implementation.
 */
secretKeyToMnemonic = (secretKey: Buffer) => Array<string>

/*
  Converts wordlist back to entropy.
 */
mnemonictoSecretKey = (Array<string>) => Buffer

/*
  Creates the master seed which is the foundation of all wallet secret keys.
  Use PBKDF2.

  Uses bitcoinjs/bip39 implementation.
 */
mnemonicToMasterSeed = (mnemonic: Array<string>) => Buffer

/*
  Hashes user password using scrypt with parameters N = 16384, r = 8, p = 1.

  Spec: SCRYPT()

  Uses scrypt-js implementation.
 */
hashPassword = (password: string) => Promise<Buffer>

/*
  Derives two symmetric secret keys from password via HKDF. Uses user ID as salt.
  * authKey is stored server side for use in authentication
  * encryptionKey is used to encrypt the secret key

  Uses futoin-hkdf implementation.

  Spec: HKDF()
 */
getHKDFKeysFromPassword = (password: string, salt: string) => Promise<{ authKey: Buffer, encryptionKey: Buffer }>

/*
  Encrypts master key using encryptionKey. Uses AEAD. Reversible.

  aead is stored server-side.

  Uses crypto-browserify/browserify-aes implementation, which polyfills Node `crypto`.

  Spec: ENC(), DEC()
 */
interface AEAD = {
  encryptedSecretKey: Buffer
  nonce: Buffer
  tag: Buffer
}
encryptSecretKey = (encryptionKey: Buffer, secretKey: Buffer) => AEAD
decryptSecretKey = (encryptionKey: Buffer, aead: AEAD) => Promise<Buffer>

/*
  Regenerates mnemonic. Because the only information the user has is their
  password, we have to go through several hash/encrypt/decrypt steps.

  aead can come from the server as it is secure.
 */
regenerateMnemonic = (aead: AEAD, password: string): Array<String>

Usage Summary

Onboarding

  1. User signs up for an account with a password (and other stuff). getEntropy() generates their keys.
  2. Secret key is used to generate mnemonic with secretKeyToMnemonic(). Asynchronously, the master seed is used to generate the master seed with mnemonicToMasterSeed().
  3. User confirms they recorded the mnemonic.
  4. Auth / encryption keys are derived from password with hashPassword() and getHKDFKeysFromPassword(). Auth key is sent to server.
  5. Encryption key is used to encrypt the secret key with encryptSecretKey(). Output is sent to server.
  6. Wallets are created with the master seed.

Logging in

  1. User submits password. Client processes into auth / encryption keys. Auth key is used to login, server responds with aead which can be decrypted using the encryption key.

Glossary

  • Auth key: Derived from password. Stored on the server side to validate sessions.
  • BIP-39: Protocol for generating master seed from private key.
  • BIP-44: Protocol for generating wallet addresses from master seed.
  • Chain: an ID for each blockchain we want to generate a private key for. Constant. TODO: Should this use the standardized chain IDs described in BIP-44, or should we make our own?
  • Encryption key: Derived from password. Used to encrypt the private key for server side storage.
  • Entropy: A secure-randomly generated bitstring composed of public and private key.
  • Master seed: Hash generated by PBKDF2(mnemonic, passphrase = "") Iteration = 2048, uses HMAC-SHA512. Should be 512 bits (64 bytes). Used to generate wallet addresses.
  • Mnemonic: A n-word phrase generated from the entropy using a wordlist. Can be used along with passphrase to (re)generate the master seed. User needs to memorize this.
  • Passphrase: An optional string for use with the PBKDF2() encryption function.
  • Password: User's login credential. Used to generate encryption key and auth key via HKDF.
  • PBKDF2: The encryption function used to generate the master seed from the mnemonic and an optional passphrase.
  • Private key: Abstracted into the mnemonic for better UX. We use this as the "master key" -- the ultimate password from which everything is derived, that should be protected at all costs. An encrypted version is stored on the server side.
  • Public key: Used to verify signatures.

Notes

External wallet keys

We will NOT support the user supplying their own wallet keys. While users will control their own wallets, we will generate the wallets for them. This is partially because we want wallets to be deterministically derivable from the master seed.

Development

Publishing to NPM

Gitlab CI will automatically publish a version if it receives a new Git tag (see also the publish_to_npm step in .gitlab-ci.yml).

Here's the specific steps: Start with decide on a new release version, eg. v1.2.3. Then create a branch and tag and push everything to Gitlab:

# Make sure you are on master and that all work for this release is committed and merged.
# Next step is to create a branch for this release:
git checkout -b release/v1.2.3

# `yarn prepare-release` will do a hard git reset, run the tests and update the version
# number based on the input you provide in the prompt. It also creates a git tag.
yarn prepare-release
git push origin release/v1.2.3

# Based on that branch, create a PR, and as soon as that is in master, push the tag
# that was created with `yarn prepare-release`:
git push origin refs/tags/v1.2.3

# At this point, the CI will run and if successful push to npm

References

FAQs

Package last updated on 22 Aug 2019

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