/*global Promise*/ (function (exports) { 'use strict'; var Keypairs = exports.Keypairs = {}; var Rasha = exports.Rasha; var Eckles = exports.Eckles; var Enc = exports.Enc || {}; Keypairs._stance = "We take the stance that if you're knowledgeable enough to" + " properly and securely use non-standard crypto then you shouldn't need Bluecrypt anyway."; Keypairs._universal = "Bluecrypt only supports crypto with standard cross-browser and cross-platform support."; Keypairs.generate = function (opts) { opts = opts || {}; var p; if (!opts.kty) { opts.kty = opts.type; } if (!opts.kty) { opts.kty = 'EC'; } if (/^EC/i.test(opts.kty)) { p = Eckles.generate(opts); } else if (/^RSA$/i.test(opts.kty)) { p = Rasha.generate(opts); } else { return Promise.Reject(new Error("'" + opts.kty + "' is not a well-supported key type." + Keypairs._universal + " Please choose 'EC', or 'RSA' if you have good reason to.")); } return p.then(function (pair) { return Keypairs.thumbprint({ jwk: pair.public }).then(function (thumb) { pair.private.kid = thumb; // maybe not the same id on the private key? pair.public.kid = thumb; return pair; }); }); }; Keypairs.export = function (opts) { return Eckles.export(opts).catch(function (err) { return Rasha.export(opts).catch(function () { return Promise.reject(err); }); }); }; /** * Chopping off the private parts is now part of the public API. * I thought it sounded a little too crude at first, but it really is the best name in every possible way. */ Keypairs.neuter = function (opts) { /** trying to find the best balance of an immutable copy with custom attributes */ var jwk = {}; Object.keys(opts.jwk).forEach(function (k) { if ('undefined' === typeof opts.jwk[k]) { return; } // ignore RSA and EC private parts if (-1 !== ['d', 'p', 'q', 'dp', 'dq', 'qi'].indexOf(k)) { return; } jwk[k] = JSON.parse(JSON.stringify(opts.jwk[k])); }); return jwk; }; Keypairs.thumbprint = function (opts) { return Promise.resolve().then(function () { if (/EC/i.test(opts.jwk.kty)) { return Eckles.thumbprint(opts); } else { return Rasha.thumbprint(opts); } }); }; Keypairs.publish = function (opts) { if ('object' !== typeof opts.jwk || !opts.jwk.kty) { throw new Error("invalid jwk: " + JSON.stringify(opts.jwk)); } /** returns a copy */ var jwk = Keypairs.neuter(opts); if (jwk.exp) { jwk.exp = setTime(jwk.exp); } else { if (opts.exp) { jwk.exp = setTime(opts.exp); } else if (opts.expiresIn) { jwk.exp = Math.round(Date.now()/1000) + opts.expiresIn; } else if (opts.expiresAt) { jwk.exp = opts.expiresAt; } } if (!jwk.use && false !== jwk.use) { jwk.use = "sig"; } if (jwk.kid) { return Promise.resolve(jwk); } return Keypairs.thumbprint({ jwk: jwk }).then(function (thumb) { jwk.kid = thumb; return jwk; }); }; // JWT a.k.a. JWS with Claims using Compact Serialization Keypairs.signJwt = function (opts) { return Keypairs.thumbprint({ jwk: opts.jwk }).then(function (thumb) { var header = opts.header || {}; var claims = JSON.parse(JSON.stringify(opts.claims || {})); header.typ = 'JWT'; if (!header.kid) { header.kid = thumb; } if (!header.alg && opts.alg) { header.alg = opts.alg; } if (!claims.iat && (false === claims.iat || false === opts.iat)) { claims.iat = undefined; } else if (!claims.iat) { claims.iat = Math.round(Date.now()/1000); } if (opts.exp) { claims.exp = setTime(opts.exp); } else if (!claims.exp && (false === claims.exp || false === opts.exp)) { claims.exp = undefined; } else if (!claims.exp) { throw new Error("opts.claims.exp should be the expiration date as seconds, human form (i.e. '1h' or '15m') or false"); } if (opts.iss) { claims.iss = opts.iss; } if (!claims.iss && (false === claims.iss || false === opts.iss)) { claims.iss = undefined; } else if (!claims.iss) { throw new Error("opts.claims.iss should be in the form of https://example.com/, a secure OIDC base url"); } return Keypairs.signJws({ jwk: opts.jwk , pem: opts.pem , protected: header , header: undefined , payload: claims }).then(function (jws) { return [ jws.protected, jws.payload, jws.signature ].join('.'); }); }); }; Keypairs.signJws = function (opts) { return Keypairs.thumbprint(opts).then(function (thumb) { function alg() { if (!opts.jwk) { throw new Error("opts.jwk must exist and must declare 'typ'"); } if (opts.jwk.alg) { return opts.jwk.alg; } var typ = ('RSA' === opts.jwk.kty) ? "RS" : "ES"; return typ + Keypairs._getBits(opts); } function sign() { var protect = opts.protected; var payload = opts.payload; // Compute JWS signature var protectedHeader = ""; // Because unprotected headers are allowed, regrettably... // https://stackoverflow.com/a/46288694 if (false !== protect) { if (!protect) { protect = {}; } if (!protect.alg) { protect.alg = alg(); } // There's a particular request where ACME / Let's Encrypt explicitly doesn't use a kid if (false === protect.kid) { protect.kid = undefined; } else if (!protect.kid) { protect.kid = thumb; } protectedHeader = JSON.stringify(protect); } // Not sure how to handle the empty case since ACME POST-as-GET must be empty //if (!payload) { // throw new Error("opts.payload should be JSON, string, or ArrayBuffer (it may be empty, but that must be explicit)"); //} // Trying to detect if it's a plain object (not Buffer, ArrayBuffer, Array, Uint8Array, etc) if (payload && ('string' !== typeof payload) && ('undefined' === typeof payload.byteLength) && ('undefined' === typeof payload.buffer) ) { payload = JSON.stringify(payload); } // Converting to a buffer, even if it was just converted to a string if ('string' === typeof payload) { payload = Enc.binToBuf(payload); } // node specifies RSA-SHAxxx even when it's actually ecdsa (it's all encoded x509 shasums anyway) var protected64 = Enc.strToUrlBase64(protectedHeader); var payload64 = Enc.bufToUrlBase64(payload); var msg = protected64 + '.' + payload64; return Keypairs._sign(opts, msg).then(function (buf) { var signedMsg = { protected: protected64 , payload: payload64 , signature: Enc.bufToUrlBase64(buf) }; console.log('Signed Base64 Msg:'); console.log(JSON.stringify(signedMsg, null, 2)); console.log('msg:', msg); return signedMsg; }); } if (opts.jwk) { return sign(); } else { return Keypairs.import({ pem: opts.pem }).then(function (pair) { opts.jwk = pair.private; return sign(); }); } }); }; Keypairs._sign = function (opts, payload) { return Keypairs._import(opts).then(function (privkey) { if ('string' === typeof payload) { payload = (new TextEncoder()).encode(payload); } return window.crypto.subtle.sign( { name: Keypairs._getName(opts) , hash: { name: 'SHA-' + Keypairs._getBits(opts) } } , privkey , payload ).then(function (signature) { signature = new Uint8Array(signature); // ArrayBuffer -> u8 // This will come back into play for CSRs, but not for JOSE if ('EC' === opts.jwk.kty && /x509/i.test(opts.format)) { signature = Keypairs._ecdsaJoseSigToAsn1Sig(signature); } return signature; }); }); }; Keypairs._getBits = function (opts) { if (opts.alg) { return opts.alg.replace(/[a-z\-]/ig, ''); } // base64 len to byte len var len = Math.floor((opts.jwk.n||'').length * 0.75); // TODO this may be a bug // need to confirm that the padding is no more or less than 1 byte if (/521/.test(opts.jwk.crv) || len >= 511) { return '512'; } else if (/384/.test(opts.jwk.crv) || len >= 383) { return '384'; } return '256'; }; Keypairs._getName = function (opts) { if (/EC/i.test(opts.jwk.kty)) { return 'ECDSA'; } else { return 'RSASSA-PKCS1-v1_5'; } }; Keypairs._import = function (opts) { return Promise.resolve().then(function () { var ops; // all private keys just happen to have a 'd' if (opts.jwk.d) { ops = [ 'sign' ]; } else { ops = [ 'verify' ]; } // gotta mark it as extractable, as if it matters opts.jwk.ext = true; opts.jwk.key_ops = ops; console.log('jwk', opts.jwk); return window.crypto.subtle.importKey( "jwk" , opts.jwk , { name: Keypairs._getName(opts) , namedCurve: opts.jwk.crv , hash: { name: 'SHA-' + Keypairs._getBits(opts) } } , true , ops ).then(function (privkey) { delete opts.jwk.ext; return privkey; }); }); }; // ECDSA JOSE / JWS / JWT signatures differ from "normal" ASN1/X509 ECDSA signatures // https://tools.ietf.org/html/rfc7518#section-3.4 Keypairs._ecdsaJoseSigToAsn1Sig = function (bufsig) { // it's easier to do the manipulation in the browser with an array bufsig = Array.from(bufsig); var hlen = bufsig.length / 2; // should be even var r = bufsig.slice(0, hlen); var s = bufsig.slice(hlen); // unpad positive ints less than 32 bytes wide while (!r[0]) { r = r.slice(1); } while (!s[0]) { s = s.slice(1); } // pad (or re-pad) ambiguously non-negative BigInts, up to 33 bytes wide if (0x80 & r[0]) { r.unshift(0); } if (0x80 & s[0]) { s.unshift(0); } var len = 2 + r.length + 2 + s.length; var head = [0x30]; // hard code 0x80 + 1 because it won't be longer than // two SHA512 plus two pad bytes (130 bytes <= 256) if (len >= 0x80) { head.push(0x81); } head.push(len); return Uint8Array.from(head.concat([0x02, r.length], r, [0x02, s.byteLength], s)); }; function setTime(time) { if ('number' === typeof time) { return time; } var t = time.match(/^(\-?\d+)([dhms])$/i); if (!t || !t[0]) { throw new Error("'" + time + "' should be datetime in seconds or human-readable format (i.e. 3d, 1h, 15m, 30s"); } var now = Math.round(Date.now()/1000); var num = parseInt(t[1], 10); var unit = t[2]; var mult = 1; switch(unit) { // fancy fallthrough, what fun! case 'd': mult *= 24; /*falls through*/ case 'h': mult *= 60; /*falls through*/ case 'm': mult *= 60; /*falls through*/ case 's': mult *= 1; } return now + (mult * num); } Enc.hexToBuf = function (hex) { var arr = []; hex.match(/.{2}/g).forEach(function (h) { arr.push(parseInt(h, 16)); }); return 'undefined' !== typeof Uint8Array ? new Uint8Array(arr) : arr; }; Enc.strToUrlBase64 = function (str) { return Enc.bufToUrlBase64(Enc.binToBuf(str)); }; Enc.binToBuf = function (bin) { var arr = bin.split('').map(function (ch) { return ch.charCodeAt(0); }); return 'undefined' !== typeof Uint8Array ? new Uint8Array(arr) : arr; }; }('undefined' !== typeof module ? module.exports : window));