moac-lightwallets
v3.0.1
Published
A lightweight moac javascript wallet.
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LightWallet
A minimal moac javascript wallet.
About
LightWallet is a HD wallet that can store your private keys encrypted in the browser to allow you to run Ethereum dapps even if you're not running a local Ethereum node. It uses BIP32 and BIP39 to generate an HD tree of addresses from a randomly generated 12-word seed.
LightWallet is primarily intended to be a signing provider for the Hooked Web3 provider through the keystore
module. This allows you to have full control over your private keys while still connecting to a remote node to relay signed transactions. Moreover, the txutils
functions can be used to construct transactions when offline, for use in e.g. air-gapped coldwallet implementations.
The default BIP32 HD derivation path is m/0'/0'/0'/i
.
Security
Please note that LightWallet has not been through a comprehensive security review at this point. It is still experimental software, intended for small amounts of Ether to be used for interacting with smart contracts on the Ethereum blockchain. Do not rely on it to store larger amounts of Ether yet.
Get Started
npm install eth-lightwallet
The eth-lightwallet
package contains dist/lightwallet.min.js
that can be included in an HTML page:
<html>
<body>
<script src="lightwallet.min.js"></script>
</body>
</html>
The file lightwallet.min.js
exposes the global object lightwallet
to the browser which has the two main modules lightwallet.keystore
and lightwallet.txutils
.
Sample usage with hooked web3 provider:
// generate a new BIP32 12-word seed
var secretSeed = lightwallet.keystore.generateRandomSeed();
// the seed is stored encrypted by a user-defined password
var password = prompt('Enter password for encryption', 'password');
lightwallet.keystore.deriveKeyFromPassword(password, function (err, pwDerivedKey) {
var ks = new lightwallet.keystore(secretSeed, pwDerivedKey);
// generate five new address/private key pairs
// the corresponding private keys are also encrypted
ks.generateNewAddress(pwDerivedKey, 5);
var addr = ks.getAddresses();
// Create a custom passwordProvider to prompt the user to enter their
// password whenever the hooked web3 provider issues a sendTransaction
// call.
ks.passwordProvider = function (callback) {
var pw = prompt("Please enter password", "Password");
callback(null, pw);
};
// Now set ks as transaction_signer in the hooked web3 provider
// and you can start using web3 using the keys/addresses in ks!
});
keystore
Function definitions
These are the interface functions for the keystore object. The keystore object holds a 12-word seed according to BIP39 spec. From this seed you can generate addresses and private keys, and use the private keys to sign transactions.
Note: Addresses and RLP encoded data are in the form of hex-strings. Hex-strings do not start with 0x
.
keystore.deriveKeyFromPassword(password, callback)
Inputs the users password and generates a symmetric key of type Uint8Array
that is used to encrypt/decrypt the keystore.
keystore(seed, pwDerivedKey [,hdPathString])
Constructor of the keystore object. The seed seed
is encrypted with pwDerivedKey
and stored encrypted in the keystore.
Inputs
- words: string defining a 12-word seed according to BIP39
- pwDerivedKey: symmetric key to encrypt the seed (Uint8Array)
keystore.isDerivedKeyCorrect(pwDerivedKey)
Returns true
if the derived key can decrypt the seed, and returns false
otherwise.
keystore.generateRandomSeed([extraEntropy])
Generates a string consisting of a random 12-word seed and returns it. If the optional argument string extraEntropy
is present the random data from the Javascript RNG will be concatenated with extraEntropy
and then hashed to produce the final seed. The string extraEntropy
can be something like entropy from mouse movements or keyboard presses, or a string representing dice throws.
keystore.isSeedValid(seed)
Checks if seed
is a valid 12-word seed according to the BIP39 specification.
keystore.addHdDerivationPath(hdPathString, pwDerivedKey, info)
Adds the HD derivation path hdPathString
to the keystore. The info
structure denotes the curve and purpose for the keys in that path. Supported structures are
{curve: 'secp256k1', purpose: 'sign'}
{curve: 'curve25519', purpose: 'asymEncrypt'}
keystore.setDefaultHdDerivationPath(hdPathString)
Set the default HD Derivation path. This path will be used if the hdPathString
is omitted from other functions. This is also the path that's used if the keystore is used with the Hooked Web3 Provider.
keystore.generateNewAddress(pwDerivedKey [, num, hdPathString])
Generates a new address/private key pair from the seed and stores them in the keystore. The private key is stored encrypted with the users password derived key. If the integer num
is supplied a batch of num
address/key pairs is generated. If hdPathString
is supplied the new key pairs are generated at that HD Path, otherwise they are generated at defaultHdPathString
.
keystore.deserialize(serialized_keystore)
Takes a serialized keystore string serialized_keystore
and returns a new keystore object.
keystore.serialize()
Serializes the current keystore object into a JSON-encoded string and returns that string.
keystore.getAddresses()
Returns a list of hex-string addresses currently stored in the keystore.
keystore.getSeed(pwDerivedKey)
Given the pwDerivedKey, decrypts and returns the users 12-word seed.
keystore.exportPrivateKey(address, pwDerivedKey)
Given the derived key, decrypts and returns the private key corresponding to address
. This should be done sparingly as the recommended practice is for the keystore
to sign transactions using signing.signTx
, so there is normally no need to export private keys.
upgrade
Function definitions
keystore.upgradeOldSerialized(oldSerialized, password, callback)
Takes a serialized keystore in an old format and a password. The callback takes the upgraded serialized keystore as its second argument.
keystore.generateNewEncryptionKeys(pwDerivedKey [, num, hdPathString])
Generate num
new encryption keys at the path hdPathString
. Only
defined when the purpose of the HD path is asymEncrypt
.
keystore.getPubKeys([hdPathString])
Return the pubkeys at hdPathString
, or at the default HD path. Only
defined when the purpose of the HD path is asymEncrypt
.
signing
Function definitions
signing.signTx(keystore, pwDerivedKey, rawTx, signingAddress, hdPathString)
Signs a transaction with the private key corresponding to signingAddress
.
Inputs
keystore
: An instance of the keystore with which to sign the TX with.pwDerivedKey
: the users password derived key (Uint8Array)rawTx
: Hex-string defining an RLP-encoded raw transaction.signingAddress
: hex-string defining the address to send the transaction from.hdPathString
: (Optional) A path at which to create the encryption keys.
Return value
Hex-string corresponding to the RLP-encoded raw transaction.
signing.signMsg(keystore, pwDerivedKey, rawMsg, signingAddress, hdPathString)
Signs a message with the private key corresponding to signingAddress
.
Inputs
keystore
: An instance of the keystore with which to sign the TX with.pwDerivedKey
: the users password derived key (Uint8Array)rawMsg
: Message to be signedsigningAddress
: hex-string defining the address corresponding to the signing private key.hdPathString
: (Optional) A path at which to create the encryption keys.
Return value
Hex-string corresponding to the RLP-encoded raw transaction.
recoverAddress(rawMsg, v, r, s)
Recovers the signing address from the message rawMsg
and the signature v, r, s
.
encryption
Function definitions
encryption.multiEncryptString(keystore, pwDerivedKey, msg, myPubKey, theirPubKeyArray [, hdPathString])
NOTE: The format of encrypted messages has not been finalized and may change at any time, so only use this for ephemeral messages that do not need to be stored encrypted for a long time.
Encrypts the string msg
with a randomly generated symmetric key, then encrypts that symmetric key assymetrically to each of the pubkeys in theirPubKeyArray
. The encrypted message can then be read only by sender and the holders of the private keys corresponding to the public keys in theirPubKeyArray
. The returned object has the following form, where nonces and ciphertexts are encoded in base64:
{ version: 1,
asymAlg: 'curve25519-xsalsa20-poly1305',
symAlg: 'xsalsa20-poly1305',
symNonce: 'SLmxcH3/CPMCCJ7orkI7iSjetRlMmzQH',
symEncMessage: 'iN4+/b5InlsVo5Bc7GTmaBh8SgWV8OBMHKHMVf7aq5O9eqwnIzVXeX4yzUWbw2w=',
encryptedSymKey:
[ { nonce: 'qcNCtKqiooYLlRuIrNlNVtF8zftoT5Cb',
ciphertext: 'L8c12EJsFYM1K7udgHDRrdHhQ7ng+VMkzOdVFTjWu0jmUzpehFeqyoEyg8cROBmm' },
{ nonce: 'puD2x3wmQKu3OIyxgJq2kG2Hz01+dxXs',
ciphertext: 'gLYtYpJbeFKXL/WAK0hyyGEelaL5Ddq9BU3249+hdZZ7xgTAZVL8tw+fIVcvpgaZ' },
{ nonce: '1g8VbftPnjc+1NG3zCGwZS8KO73yjucu',
ciphertext: 'pftERJOPDV2dfP+C2vOwPWT43Q89V74Nfu1arNQeTMphSHqVuUXItbyCMizISTxG' },
{ nonce: 'KAH+cCxbFGSDjHDOBzDhMboQdFWepvBw',
ciphertext: 'XWmmBmxLEyLTUmUBiWy2wDqedubsa0KTcufhKM7YfJn/eHWhDDptMxYDvaKisFmn' } ] }
Note that no padding is applied to msg
, so it's possible to deduce the length of the string msg
from the ciphertext. If you don't want this information to be known, please apply padding to msg
before calling this function.
encryption.multiDecryptString(keystore, pwDerivedKey, encMsg, theirPubKey, myPubKey [, hdPathString])
Decrypt a message encMsg
created with the function
multiEncryptString()
. If successful, returns the original message
string. If not successful, returns false
.
txutils
Function definitions
These are the interface functions for the txutils
module. These functions will create RLP encoded raw unsigned transactions which can be signed using the keystore.signTx()
command.
txutils.createContractTx(fromAddress, txObject)
Using the data in txObject
, creates an RLP-encoded transaction that will create the contract with compiled bytecode defined by txObject.data
. Also computes the address of the created contract.
Inputs
fromAddress
: Address to send the transaction fromtxObject.gasLimit
: Gas limittxObject.gasPrice
: Gas pricetxObject.value
: Endowment (optional)txObject.nonce
: Nonce offromAddress
txObject.data
: Compiled code of the contract
Output
Object obj
with fields
obj.tx
: RLP encoded transaction (hex string)obj.addr
: Address of the created contract
txutils.functionTx(abi, functionName, args, txObject)
Creates a transaction calling a function with name functionName
, with arguments args
conforming to abi
. The function is defined in a contract with address txObject.to
.
Inputs
abi
: Json-formatted ABI as returned from thesolc
compilerfunctionName
: string with the function nameargs
: Array with the arguments to the functiontxObject.to
: Address of the contracttxObject.gasLimit
: Gas limittxObject.gasPrice
: Gas pricetxObject.value
: Value to sendtxObject.nonce
: Nonce of sending address
Output
RLP-encoded hex string defining the transaction.
txutils.valueTx(txObject)
Creates a transaction sending value to txObject.to
.
Inputs
txObject.to
: Address to send totxObject.gasLimit
: Gas limittxObject.gasPrice
: Gas pricetxObject.value
: Value to sendtxObject.nonce
: Nonce of sending address
Output
RLP-encoded hex string defining the transaction.
Examples
See the file example_usage.js
for usage of keystore
and txutils
in node.
See the file example_web.html
for an example of how to use the LightWallet keystore together with the Hooked Web3 Provider in the browser.
Tests
Run all tests:
npm run test
npm run coverage
License
MIT License.