/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this file, * You can obtain one at http://mozilla.org/MPL/2.0/. */ const {classes: Cc, interfaces: Ci, results: Cr, utils: Cu} = Components; this.EXPORTED_SYMBOLS = ["CryptoUtils"]; Cu.import("resource://services-common/observers.js"); Cu.import("resource://services-common/utils.js"); Cu.import("resource://gre/modules/XPCOMUtils.jsm"); this.CryptoUtils = { /** * Generate a string of random bytes. */ generateRandomBytes: function generateRandomBytes(length) { let rng = Cc["@mozilla.org/security/random-generator;1"] .createInstance(Ci.nsIRandomGenerator); let bytes = rng.generateRandomBytes(length); return CommonUtils.byteArrayToString(bytes); }, /** * UTF8-encode a message and hash it with the given hasher. Returns a * string containing bytes. The hasher is reset if it's an HMAC hasher. */ digestUTF8: function digestUTF8(message, hasher) { let data = this._utf8Converter.convertToByteArray(message, {}); hasher.update(data, data.length); let result = hasher.finish(false); if (hasher instanceof Ci.nsICryptoHMAC) { hasher.reset(); } return result; }, /** * Treat the given message as a bytes string and hash it with the given * hasher. Returns a string containing bytes. The hasher is reset if it's * an HMAC hasher. */ digestBytes: function digestBytes(message, hasher) { // No UTF-8 encoding for you, sunshine. let bytes = [b.charCodeAt() for each (b in message)]; hasher.update(bytes, bytes.length); let result = hasher.finish(false); if (hasher instanceof Ci.nsICryptoHMAC) { hasher.reset(); } return result; }, /** * UTF-8 encode a message and perform a SHA-1 over it. * * @param message * (string) Buffer to perform operation on. Should be a JS string. * It is possible to pass in a string representing an array * of bytes. But, you probably don't want to UTF-8 encode * such data and thus should not be using this function. * * @return string * Raw bytes constituting SHA-1 hash. Value is a JS string. Each * character is the byte value for that offset. Returned string * always has .length == 20. */ UTF8AndSHA1: function UTF8AndSHA1(message) { let hasher = Cc["@mozilla.org/security/hash;1"] .createInstance(Ci.nsICryptoHash); hasher.init(hasher.SHA1); return CryptoUtils.digestUTF8(message, hasher); }, sha1: function sha1(message) { return CommonUtils.bytesAsHex(CryptoUtils.UTF8AndSHA1(message)); }, sha1Base32: function sha1Base32(message) { return CommonUtils.encodeBase32(CryptoUtils.UTF8AndSHA1(message)); }, /** * Produce an HMAC key object from a key string. */ makeHMACKey: function makeHMACKey(str) { return Svc.KeyFactory.keyFromString(Ci.nsIKeyObject.HMAC, str); }, /** * Produce an HMAC hasher and initialize it with the given HMAC key. */ makeHMACHasher: function makeHMACHasher(type, key) { let hasher = Cc["@mozilla.org/security/hmac;1"] .createInstance(Ci.nsICryptoHMAC); hasher.init(type, key); return hasher; }, /** * HMAC-based Key Derivation Step 2 according to RFC 5869. */ hkdfExpand: function hkdfExpand(prk, info, len) { const BLOCKSIZE = 256 / 8; let h = CryptoUtils.makeHMACHasher(Ci.nsICryptoHMAC.SHA256, CryptoUtils.makeHMACKey(prk)); let T = ""; let Tn = ""; let iterations = Math.ceil(len/BLOCKSIZE); for (let i = 0; i < iterations; i++) { Tn = CryptoUtils.digestBytes(Tn + info + String.fromCharCode(i + 1), h); T += Tn; } return T.slice(0, len); }, /** * PBKDF2 implementation in Javascript. * * The arguments to this function correspond to items in * PKCS #5, v2.0 pp. 9-10 * * P: the passphrase, an octet string: e.g., "secret phrase" * S: the salt, an octet string: e.g., "DNXPzPpiwn" * c: the number of iterations, a positive integer: e.g., 4096 * dkLen: the length in octets of the destination * key, a positive integer: e.g., 16 * * The output is an octet string of length dkLen, which you * can encode as you wish. */ pbkdf2Generate : function pbkdf2Generate(P, S, c, dkLen) { // We don't have a default in the algo itself, as NSS does. // Use the constant. if (!dkLen) { dkLen = SYNC_KEY_DECODED_LENGTH; } /* For HMAC-SHA-1 */ const HLEN = 20; function F(S, c, i, h) { function XOR(a, b, isA) { if (a.length != b.length) { return false; } let val = []; for (let i = 0; i < a.length; i++) { if (isA) { val[i] = a[i] ^ b[i]; } else { val[i] = a.charCodeAt(i) ^ b.charCodeAt(i); } } return val; } let ret; let U = []; /* Encode i into 4 octets: _INT */ let I = []; I[0] = String.fromCharCode((i >> 24) & 0xff); I[1] = String.fromCharCode((i >> 16) & 0xff); I[2] = String.fromCharCode((i >> 8) & 0xff); I[3] = String.fromCharCode(i & 0xff); U[0] = CryptoUtils.digestBytes(S + I.join(''), h); for (let j = 1; j < c; j++) { U[j] = CryptoUtils.digestBytes(U[j - 1], h); } ret = U[0]; for (j = 1; j < c; j++) { ret = CommonUtils.byteArrayToString(XOR(ret, U[j])); } return ret; } let l = Math.ceil(dkLen / HLEN); let r = dkLen - ((l - 1) * HLEN); // Reuse the key and the hasher. Remaking them 4096 times is 'spensive. let h = CryptoUtils.makeHMACHasher(Ci.nsICryptoHMAC.SHA1, CryptoUtils.makeHMACKey(P)); T = []; for (let i = 0; i < l;) { T[i] = F(S, c, ++i, h); } let ret = ""; for (i = 0; i < l-1;) { ret += T[i++]; } ret += T[l - 1].substr(0, r); return ret; }, deriveKeyFromPassphrase: function deriveKeyFromPassphrase(passphrase, salt, keyLength, forceJS) { if (Svc.Crypto.deriveKeyFromPassphrase && !forceJS) { return Svc.Crypto.deriveKeyFromPassphrase(passphrase, salt, keyLength); } else { // Fall back to JS implementation. // 4096 is hardcoded in WeaveCrypto, so do so here. return CryptoUtils.pbkdf2Generate(passphrase, atob(salt), 4096, keyLength); } }, /** * Compute the HTTP MAC SHA-1 for an HTTP request. * * @param identifier * (string) MAC Key Identifier. * @param key * (string) MAC Key. * @param method * (string) HTTP request method. * @param URI * (nsIURI) HTTP request URI. * @param extra * (object) Optional extra parameters. Valid keys are: * nonce_bytes - How many bytes the nonce should be. This defaults * to 8. Note that this many bytes are Base64 encoded, so the * string length of the nonce will be longer than this value. * ts - Timestamp to use. Should only be defined for testing. * nonce - String nonce. Should only be defined for testing as this * function will generate a cryptographically secure random one * if not defined. * ext - Extra string to be included in MAC. Per the HTTP MAC spec, * the format is undefined and thus application specific. * @returns * (object) Contains results of operation and input arguments (for * symmetry). The object has the following keys: * * identifier - (string) MAC Key Identifier (from arguments). * key - (string) MAC Key (from arguments). * method - (string) HTTP request method (from arguments). * hostname - (string) HTTP hostname used (derived from arguments). * port - (string) HTTP port number used (derived from arguments). * mac - (string) Raw HMAC digest bytes. * getHeader - (function) Call to obtain the string Authorization * header value for this invocation. * nonce - (string) Nonce value used. * ts - (number) Integer seconds since Unix epoch that was used. */ computeHTTPMACSHA1: function computeHTTPMACSHA1(identifier, key, method, uri, extra) { let ts = (extra && extra.ts) ? extra.ts : Math.floor(Date.now() / 1000); let nonce_bytes = (extra && extra.nonce_bytes > 0) ? extra.nonce_bytes : 8; // We are allowed to use more than the Base64 alphabet if we want. let nonce = (extra && extra.nonce) ? extra.nonce : btoa(CryptoUtils.generateRandomBytes(nonce_bytes)); let host = uri.asciiHost; let port; let usedMethod = method.toUpperCase(); if (uri.port != -1) { port = uri.port; } else if (uri.scheme == "http") { port = "80"; } else if (uri.scheme == "https") { port = "443"; } else { throw new Error("Unsupported URI scheme: " + uri.scheme); } let ext = (extra && extra.ext) ? extra.ext : ""; let requestString = ts.toString(10) + "\n" + nonce + "\n" + usedMethod + "\n" + uri.path + "\n" + host + "\n" + port + "\n" + ext + "\n"; let hasher = CryptoUtils.makeHMACHasher(Ci.nsICryptoHMAC.SHA1, CryptoUtils.makeHMACKey(key)); let mac = CryptoUtils.digestBytes(requestString, hasher); function getHeader() { return CryptoUtils.getHTTPMACSHA1Header(this.identifier, this.ts, this.nonce, this.mac, this.ext); } return { identifier: identifier, key: key, method: usedMethod, hostname: host, port: port, mac: mac, nonce: nonce, ts: ts, ext: ext, getHeader: getHeader }; }, /** * Obtain the HTTP MAC Authorization header value from fields. * * @param identifier * (string) MAC key identifier. * @param ts * (number) Integer seconds since Unix epoch. * @param nonce * (string) Nonce value. * @param mac * (string) Computed HMAC digest (raw bytes). * @param ext * (optional) (string) Extra string content. * @returns * (string) Value to put in Authorization header. */ getHTTPMACSHA1Header: function getHTTPMACSHA1Header(identifier, ts, nonce, mac, ext) { let header ='MAC id="' + identifier + '", ' + 'ts="' + ts + '", ' + 'nonce="' + nonce + '", ' + 'mac="' + btoa(mac) + '"'; if (!ext) { return header; } return header += ', ext="' + ext +'"'; }, }; XPCOMUtils.defineLazyGetter(CryptoUtils, "_utf8Converter", function() { let converter = Cc["@mozilla.org/intl/scriptableunicodeconverter"] .createInstance(Ci.nsIScriptableUnicodeConverter); converter.charset = "UTF-8"; return converter; }); let Svc = {}; XPCOMUtils.defineLazyServiceGetter(Svc, "KeyFactory", "@mozilla.org/security/keyobjectfactory;1", "nsIKeyObjectFactory"); Svc.__defineGetter__("Crypto", function() { let ns = {}; Cu.import("resource://services-crypto/WeaveCrypto.js", ns); let wc = new ns.WeaveCrypto(); delete Svc.Crypto; return Svc.Crypto = wc; }); Observers.add("xpcom-shutdown", function unloadServices() { Observers.remove("xpcom-shutdown", unloadServices); for (let k in Svc) { delete Svc[k]; } });