bitmessage-js/lib/crypto.js

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/**
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* Isomorphic Bitmessage crypto module. Reexports platform-dependent
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* implementations and also some common routines.
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* @module bitmessage/crypto
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*/
"use strict";
var eccrypto = require("eccrypto");
var assert = require("./_util").assert;
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var platform = require("./platform");
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var PPromise = platform.Promise;
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/**
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* Calculate SHA-1 hash.
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* @param {Buffer} buf - Input data
* @return {Buffer} Resulting hash.
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* @function
* @static
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*/
var sha1 = exports.sha1 = platform.sha1;
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/**
* Calculate SHA-256 hash.
* @param {Buffer} buf - Input data
* @return {Buffer} Resulting hash.
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* @function
*/
exports.sha256 = platform.sha256;
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/**
* Calculate SHA-512 hash.
* @param {Buffer} buf - Input data
* @return {Buffer} Resulting hash.
* @function
*/
exports.sha512 = platform.sha512;
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/**
* Calculate RIPEMD-160 hash.
* @param {Buffer} buf - Input data
* @return {Buffer} Resulting hash.
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* @function
*/
exports.ripemd160 = platform.ripemd160;
/**
* Generate cryptographically strong pseudo-random data.
* @param {number} size - Number of bytes
* @return {Buffer} Buffer with random data.
* @function
*/
exports.randomBytes = platform.randomBytes;
/**
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* Generate a new random private key.
* @return {Buffer} New private key.
*/
exports.getPrivate = function() {
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return platform.randomBytes(32);
};
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/**
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* Generate public key for the given private key.
* @param {Buffer} privateKey - A 32-byte private key
* @return {Buffer} A 65-byte (uncompressed) public key.
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* @function
*/
exports.getPublic = eccrypto.getPublic;
/**
* Sign message using ecdsa-with-sha1 scheme.
* @param {Buffer} privateKey - A 32-byte private key
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* @param {Buffer} msg - The message being signed
* @return {Promise.<Buffer>} A promise that contains signature in DER
* format when fulfilled.
*/
exports.sign = function(privateKey, msg) {
var hash = sha1(msg);
return eccrypto.sign(privateKey, hash);
};
/**
* Verify signature using ecdsa-with-sha1 scheme.
* @param {Buffer} publicKey - A 65-byte public key
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* @param {Buffer} msg - The message being verified
* @param {Buffer} sig - The signature in DER format
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* @return {Promise.<null>} A promise that resolves on correct signature
* and rejects on bad key or signature.
*/
exports.verify = function(publicKey, msg, sig) {
var hash = sha1(msg);
return eccrypto.verify(publicKey, hash, sig);
};
var SECP256K1_TYPE = 714;
// We define this structure here to avoid circular imports. However we
// rexport and document it in `structs` module for consistency.
var encrypted = exports.encrypted = {
decode: function(buf) {
assert(buf.length >= 118, "Buffer is too small");
assert(buf.readUInt16BE(16, true) === SECP256K1_TYPE, "Bad curve type");
assert(buf.readUInt16BE(18, true) === 32, "Bad Rx length");
assert(buf.readUInt16BE(52, true) === 32, "Bad Ry length");
var iv = Buffer.alloc(16);
buf.copy(iv, 0, 0, 16);
var ephemPublicKey = Buffer.alloc(70);
buf.copy(ephemPublicKey, 0, 16, 86);
// NOTE(Kagami): We do copy instead of slice to protect against
// possible source buffer modification by user.
var ciphertext = Buffer.alloc(buf.length - 118);
buf.copy(ciphertext, 0, 86, buf.length - 32);
var mac = Buffer.alloc(32);
buf.copy(mac, 0, buf.length - 32);
return {
iv: iv,
ephemPublicKey: ephemPublicKey,
ciphertext: ciphertext,
mac: mac,
};
},
encode: function(opts) {
assert(opts.iv.length === 16, "Bad IV");
assert(opts.ephemPublicKey.length === 70, "Bad public key");
assert(
opts.ephemPublicKey.readUInt16BE(0, true) === SECP256K1_TYPE,
"Bad curve type");
assert(opts.mac.length === 32, "Bad MAC");
return Buffer.concat(
[opts.iv, opts.ephemPublicKey, opts.ciphertext, opts.mac]);
},
};
/**
* Encrypt message for given recepient's public key.
* @param {Buffer} publicKeyTo - Recipient's public key (65 bytes)
* @param {Buffer} msg - The message being encrypted
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* @param {Object=} opts - You may also specify initialization vector
* and ephemeral private key to get deterministic results
* @param {Buffer} opts.iv - Initialization vector (16 bytes)
* @param {Buffer} opts.ephemPrivateKey - Ephemeral private key (32
* bytes)
* @return {Promise.<Buffer>} A promise that resolves with the buffer in
* `encrypted` format successful encryption and rejects on failure.
*/
exports.encrypt = function(publicKeyTo, msg, opts) {
return eccrypto.encrypt(publicKeyTo, msg, opts).then(function(encObj) {
return encrypted.encode(encObj);
});
};
/**
* Decrypt message using given private key.
* @param {Buffer} privateKey - A 32-byte private key of recepient of
* the mesage
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* @param {Buffer} buf - Encrypted data
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* @return {Promise.<Buffer>} A promise that resolves with the plaintext
* on successful decryption and rejects on failure.
*/
exports.decrypt = function(privateKey, buf) {
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return new PPromise(function(resolve) {
var encObj = encrypted.decode(buf);
resolve(eccrypto.decrypt(privateKey, encObj));
});
};