// Copyright 2015-2019 AJ ONeal. All rights reserved /* 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/. */ ; (function (exports) { var Enc = exports.Enc = {}; Enc.bufToBin = function (buf) { var bin = ''; // cannot use .map() because Uint8Array would return only 0s buf.forEach(function (ch) { bin += String.fromCharCode(ch); }); return bin; }; Enc.bufToHex = function toHex(u8) { var hex = []; var i, h; var len = (u8.byteLength || u8.length); for (i = 0; i < len; i += 1) { h = u8[i].toString(16); if (h.length % 2) { h = '0' + h; } hex.push(h); } return hex.join('').toLowerCase(); }; Enc.urlBase64ToBase64 = function urlsafeBase64ToBase64(str) { var r = str % 4; if (2 === r) { str += '=='; } else if (3 === r) { str += '='; } return str.replace(/-/g, '+').replace(/_/g, '/'); }; Enc.base64ToBuf = function (b64) { return Enc.binToBuf(atob(b64)); }; Enc.binToBuf = function (bin) { var arr = bin.split('').map(function (ch) { return ch.charCodeAt(0); }); return 'undefined' !== typeof Uint8Array ? new Uint8Array(arr) : arr; }; Enc.bufToHex = function (u8) { var hex = []; var i, h; var len = (u8.byteLength || u8.length); for (i = 0; i < len; i += 1) { h = u8[i].toString(16); if (h.length % 2) { h = '0' + h; } hex.push(h); } return hex.join('').toLowerCase(); }; Enc.numToHex = function (d) { d = d.toString(16); if (d.length % 2) { return '0' + d; } return d; }; Enc.bufToUrlBase64 = function (u8) { return Enc.base64ToUrlBase64(Enc.bufToBase64(u8)); }; Enc.base64ToUrlBase64 = function (str) { return str.replace(/\+/g, '-').replace(/\//g, '_').replace(/=/g, ''); }; Enc.bufToBase64 = function (u8) { var bin = ''; u8.forEach(function (i) { bin += String.fromCharCode(i); }); return btoa(bin); }; 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.numToHex = function (d) { d = d.toString(16); if (d.length % 2) { return '0' + d; } return d; }; // // JWK to SSH (tested working) // Enc.base64ToHex = function (b64) { var bin = atob(Enc.urlBase64ToBase64(b64)); return Enc.binToHex(bin); }; Enc.binToHex = function (bin) { return bin.split('').map(function (ch) { var h = ch.charCodeAt(0).toString(16); if (h.length % 2) { h = '0' + h; } return h; }).join(''); }; // TODO are there any nuance differences here? Enc.utf8ToHex = Enc.binToHex; Enc.hexToBase64 = function (hex) { return btoa(Enc.hexToBin(hex)); }; Enc.hexToBin = function (hex) { return hex.match(/.{2}/g).map(function (h) { return String.fromCharCode(parseInt(h, 16)); }).join(''); }; Enc.urlBase64ToBase64 = function urlsafeBase64ToBase64(str) { var r = str % 4; if (2 === r) { str += '=='; } else if (3 === r) { str += '='; } return str.replace(/-/g, '+').replace(/_/g, '/'); }; }('undefined' !== typeof exports ? module.exports : window )); ;(function (exports) { 'use strict'; if (!exports.ASN1) { exports.ASN1 = {}; } if (!exports.Enc) { exports.Enc = {}; } if (!exports.PEM) { exports.PEM = {}; } var ASN1 = exports.ASN1; var Enc = exports.Enc; var PEM = exports.PEM; // // Packer // // Almost every ASN.1 type that's important for CSR // can be represented generically with only a few rules. exports.ASN1 = function ASN1(/*type, hexstrings...*/) { var args = Array.prototype.slice.call(arguments); var typ = args.shift(); var str = args.join('').replace(/\s+/g, '').toLowerCase(); var len = (str.length/2); var lenlen = 0; var hex = typ; // We can't have an odd number of hex chars if (len !== Math.round(len)) { throw new Error("invalid hex"); } // The first byte of any ASN.1 sequence is the type (Sequence, Integer, etc) // The second byte is either the size of the value, or the size of its size // 1. If the second byte is < 0x80 (128) it is considered the size // 2. If it is > 0x80 then it describes the number of bytes of the size // ex: 0x82 means the next 2 bytes describe the size of the value // 3. The special case of exactly 0x80 is "indefinite" length (to end-of-file) if (len > 127) { lenlen += 1; while (len > 255) { lenlen += 1; len = len >> 8; } } if (lenlen) { hex += Enc.numToHex(0x80 + lenlen); } return hex + Enc.numToHex(str.length/2) + str; }; // The Integer type has some special rules ASN1.UInt = function UINT() { var str = Array.prototype.slice.call(arguments).join(''); var first = parseInt(str.slice(0, 2), 16); // If the first byte is 0x80 or greater, the number is considered negative // Therefore we add a '00' prefix if the 0x80 bit is set if (0x80 & first) { str = '00' + str; } return ASN1('02', str); }; // The Bit String type also has a special rule ASN1.BitStr = function BITSTR() { var str = Array.prototype.slice.call(arguments).join(''); // '00' is a mask of how many bits of the next byte to ignore return ASN1('03', '00' + str); }; ASN1.pack = function (arr) { var typ = Enc.numToHex(arr[0]); var str = ''; if (Array.isArray(arr[1])) { arr[1].forEach(function (a) { str += ASN1.pack(a); }); } else if ('string' === typeof arr[1]) { str = arr[1]; } else { throw new Error("unexpected array"); } if ('03' === typ) { return ASN1.BitStr(str); } else if ('02' === typ) { return ASN1.UInt(str); } else { return ASN1(typ, str); } }; Object.keys(ASN1).forEach(function (k) { exports.ASN1[k] = ASN1[k]; }); ASN1 = exports.ASN1; PEM.packBlock = function (opts) { // TODO allow for headers? return '-----BEGIN ' + opts.type + '-----\n' + Enc.bufToBase64(opts.bytes).match(/.{1,64}/g).join('\n') + '\n' + '-----END ' + opts.type + '-----' ; }; Enc.bufToBase64 = function (u8) { var bin = ''; u8.forEach(function (i) { bin += String.fromCharCode(i); }); return btoa(bin); }; 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.numToHex = function (d) { d = d.toString(16); if (d.length % 2) { return '0' + d; } return d; }; }('undefined' !== typeof window ? window : module.exports)); (function (exports) { 'use strict'; var x509 = exports.x509 = {}; var ASN1 = exports.ASN1; var Enc = exports.Enc; // 1.2.840.10045.3.1.7 // prime256v1 (ANSI X9.62 named elliptic curve) var OBJ_ID_EC = '06 08 2A8648CE3D030107'.replace(/\s+/g, '').toLowerCase(); // 1.3.132.0.34 // secp384r1 (SECG (Certicom) named elliptic curve) var OBJ_ID_EC_384 = '06 05 2B81040022'.replace(/\s+/g, '').toLowerCase(); // 1.2.840.10045.2.1 // ecPublicKey (ANSI X9.62 public key type) var OBJ_ID_EC_PUB = '06 07 2A8648CE3D0201'.replace(/\s+/g, '').toLowerCase(); x509.parseSec1 = function parseEcOnlyPrivkey(u8, jwk) { var index = 7; var len = 32; var olen = OBJ_ID_EC.length / 2; if ("P-384" === jwk.crv) { olen = OBJ_ID_EC_384.length / 2; index = 8; len = 48; } if (len !== u8[index - 1]) { throw new Error("Unexpected bitlength " + len); } // private part is d var d = u8.slice(index, index + len); // compression bit index var ci = index + len + 2 + olen + 2 + 3; var c = u8[ci]; var x, y; if (0x04 === c) { y = u8.slice(ci + 1 + len, ci + 1 + len + len); } else if (0x02 !== c) { throw new Error("not a supported EC private key"); } x = u8.slice(ci + 1, ci + 1 + len); return { kty: jwk.kty , crv: jwk.crv , d: Enc.bufToUrlBase64(d) //, dh: Enc.bufToHex(d) , x: Enc.bufToUrlBase64(x) //, xh: Enc.bufToHex(x) , y: Enc.bufToUrlBase64(y) //, yh: Enc.bufToHex(y) }; }; x509.packPkcs1 = function (jwk) { var n = ASN1.UInt(Enc.base64ToHex(jwk.n)); var e = ASN1.UInt(Enc.base64ToHex(jwk.e)); if (!jwk.d) { return Enc.hexToBuf(ASN1('30', n, e)); } return Enc.hexToBuf(ASN1('30' , ASN1.UInt('00') , n , e , ASN1.UInt(Enc.base64ToHex(jwk.d)) , ASN1.UInt(Enc.base64ToHex(jwk.p)) , ASN1.UInt(Enc.base64ToHex(jwk.q)) , ASN1.UInt(Enc.base64ToHex(jwk.dp)) , ASN1.UInt(Enc.base64ToHex(jwk.dq)) , ASN1.UInt(Enc.base64ToHex(jwk.qi)) )); }; x509.parsePkcs8 = function parseEcPkcs8(u8, jwk) { var index = 24 + (OBJ_ID_EC.length / 2); var len = 32; if ("P-384" === jwk.crv) { index = 24 + (OBJ_ID_EC_384.length / 2) + 2; len = 48; } //console.log(index, u8.slice(index)); if (0x04 !== u8[index]) { //console.log(jwk); throw new Error("privkey not found"); } var d = u8.slice(index + 2, index + 2 + len); var ci = index + 2 + len + 5; var xi = ci + 1; var x = u8.slice(xi, xi + len); var yi = xi + len; var y; if (0x04 === u8[ci]) { y = u8.slice(yi, yi + len); } else if (0x02 !== u8[ci]) { throw new Error("invalid compression bit (expected 0x04 or 0x02)"); } return { kty: jwk.kty , crv: jwk.crv , d: Enc.bufToUrlBase64(d) //, dh: Enc.bufToHex(d) , x: Enc.bufToUrlBase64(x) //, xh: Enc.bufToHex(x) , y: Enc.bufToUrlBase64(y) //, yh: Enc.bufToHex(y) }; }; x509.parseSpki = function parsePem(u8, jwk) { var ci = 16 + OBJ_ID_EC.length / 2; var len = 32; if ("P-384" === jwk.crv) { ci = 16 + OBJ_ID_EC_384.length / 2; len = 48; } var c = u8[ci]; var xi = ci + 1; var x = u8.slice(xi, xi + len); var yi = xi + len; var y; if (0x04 === c) { y = u8.slice(yi, yi + len); } else if (0x02 !== c) { throw new Error("not a supported EC private key"); } return { kty: jwk.kty , crv: jwk.crv , x: Enc.bufToUrlBase64(x) //, xh: Enc.bufToHex(x) , y: Enc.bufToUrlBase64(y) //, yh: Enc.bufToHex(y) }; }; x509.parsePkix = x509.parseSpki; x509.packSec1 = function (jwk) { var d = Enc.base64ToHex(jwk.d); var x = Enc.base64ToHex(jwk.x); var y = Enc.base64ToHex(jwk.y); var objId = ('P-256' === jwk.crv) ? OBJ_ID_EC : OBJ_ID_EC_384; return Enc.hexToBuf( ASN1('30' , ASN1.UInt('01') , ASN1('04', d) , ASN1('A0', objId) , ASN1('A1', ASN1.BitStr('04' + x + y))) ); }; /** * take a private jwk and creates a der from it * @param {*} jwk */ x509.packPkcs8 = function (jwk) { if ('RSA' === jwk.kty) { if (!jwk.d) { // Public RSA return Enc.hexToBuf(ASN1('30' , ASN1('30' , ASN1('06', '2a864886f70d010101') , ASN1('05') ) , ASN1.BitStr(ASN1('30' , ASN1.UInt(Enc.base64ToHex(jwk.n)) , ASN1.UInt(Enc.base64ToHex(jwk.e)) )) )); } // Private RSA return Enc.hexToBuf(ASN1('30' , ASN1.UInt('00') , ASN1('30' , ASN1('06', '2a864886f70d010101') , ASN1('05') ) , ASN1('04' , ASN1('30' , ASN1.UInt('00') , ASN1.UInt(Enc.base64ToHex(jwk.n)) , ASN1.UInt(Enc.base64ToHex(jwk.e)) , ASN1.UInt(Enc.base64ToHex(jwk.d)) , ASN1.UInt(Enc.base64ToHex(jwk.p)) , ASN1.UInt(Enc.base64ToHex(jwk.q)) , ASN1.UInt(Enc.base64ToHex(jwk.dp)) , ASN1.UInt(Enc.base64ToHex(jwk.dq)) , ASN1.UInt(Enc.base64ToHex(jwk.qi)) ) ) )); } var d = Enc.base64ToHex(jwk.d); var x = Enc.base64ToHex(jwk.x); var y = Enc.base64ToHex(jwk.y); var objId = ('P-256' === jwk.crv) ? OBJ_ID_EC : OBJ_ID_EC_384; return Enc.hexToBuf( ASN1('30' , ASN1.UInt('00') , ASN1('30' , OBJ_ID_EC_PUB , objId ) , ASN1('04' , ASN1('30' , ASN1.UInt('01') , ASN1('04', d) , ASN1('A1', ASN1.BitStr('04' + x + y))))) ); }; x509.packSpki = function (jwk) { if (/EC/i.test(jwk.kty)) { return x509.packSpkiEc(jwk); } return x509.packSpkiRsa(jwk); }; x509.packSpkiRsa = function (jwk) { if (!jwk.d) { // Public RSA return Enc.hexToBuf(ASN1('30' , ASN1('30' , ASN1('06', '2a864886f70d010101') , ASN1('05') ) , ASN1.BitStr(ASN1('30' , ASN1.UInt(Enc.base64ToHex(jwk.n)) , ASN1.UInt(Enc.base64ToHex(jwk.e)) )) )); } // Private RSA return Enc.hexToBuf(ASN1('30' , ASN1.UInt('00') , ASN1('30' , ASN1('06', '2a864886f70d010101') , ASN1('05') ) , ASN1('04' , ASN1('30' , ASN1.UInt('00') , ASN1.UInt(Enc.base64ToHex(jwk.n)) , ASN1.UInt(Enc.base64ToHex(jwk.e)) , ASN1.UInt(Enc.base64ToHex(jwk.d)) , ASN1.UInt(Enc.base64ToHex(jwk.p)) , ASN1.UInt(Enc.base64ToHex(jwk.q)) , ASN1.UInt(Enc.base64ToHex(jwk.dp)) , ASN1.UInt(Enc.base64ToHex(jwk.dq)) , ASN1.UInt(Enc.base64ToHex(jwk.qi)) ) ) )); }; x509.packSpkiEc = function (jwk) { var x = Enc.base64ToHex(jwk.x); var y = Enc.base64ToHex(jwk.y); var objId = ('P-256' === jwk.crv) ? OBJ_ID_EC : OBJ_ID_EC_384; return Enc.hexToBuf( ASN1('30' , ASN1('30' , OBJ_ID_EC_PUB , objId ) , ASN1.BitStr('04' + x + y)) ); }; x509.packPkix = x509.packSpki; }('undefined' !== typeof module ? module.exports : window)); /*global Promise*/ (function (exports) { 'use strict'; var EC = exports.Eckles = {}; var x509 = exports.x509; if ('undefined' !== typeof module) { module.exports = EC; } var PEM = exports.PEM; var SSH = exports.SSH; var Enc = {}; var textEncoder = new TextEncoder(); EC._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."; EC._universal = "Bluecrypt only supports crypto with standard cross-browser and cross-platform support."; EC.generate = function (opts) { var wcOpts = {}; if (!opts) { opts = {}; } if (!opts.kty) { opts.kty = 'EC'; } // ECDSA has only the P curves and an associated bitlength wcOpts.name = 'ECDSA'; if (!opts.namedCurve) { opts.namedCurve = 'P-256'; } wcOpts.namedCurve = opts.namedCurve; // true for supported curves if (/256/.test(wcOpts.namedCurve)) { wcOpts.namedCurve = 'P-256'; wcOpts.hash = { name: "SHA-256" }; } else if (/384/.test(wcOpts.namedCurve)) { wcOpts.namedCurve = 'P-384'; wcOpts.hash = { name: "SHA-384" }; } else { return Promise.Reject(new Error("'" + wcOpts.namedCurve + "' is not an NIST approved ECDSA namedCurve. " + " Please choose either 'P-256' or 'P-384'. " + EC._stance)); } var extractable = true; return window.crypto.subtle.generateKey( wcOpts , extractable , [ 'sign', 'verify' ] ).then(function (result) { return window.crypto.subtle.exportKey( "jwk" , result.privateKey ).then(function (privJwk) { privJwk.key_ops = undefined; privJwk.ext = undefined; return { private: privJwk , public: EC.neuter({ jwk: privJwk }) }; }); }); }; EC.export = function (opts) { return Promise.resolve().then(function () { if (!opts || !opts.jwk || 'object' !== typeof opts.jwk) { throw new Error("must pass { jwk: jwk } as a JSON object"); } var jwk = JSON.parse(JSON.stringify(opts.jwk)); var format = opts.format; if (opts.public || -1 !== [ 'spki', 'pkix', 'ssh', 'rfc4716' ].indexOf(format)) { jwk.d = null; } if ('EC' !== jwk.kty) { throw new Error("options.jwk.kty must be 'EC' for EC keys"); } if (!jwk.d) { if (!format || -1 !== [ 'spki', 'pkix' ].indexOf(format)) { format = 'spki'; } else if (-1 !== [ 'ssh', 'rfc4716' ].indexOf(format)) { format = 'ssh'; } else { throw new Error("options.format must be 'spki' or 'ssh' for public EC keys, not (" + typeof format + ") " + format); } } else { if (!format || 'sec1' === format) { format = 'sec1'; } else if ('pkcs8' !== format) { throw new Error("options.format must be 'sec1' or 'pkcs8' for private EC keys, not '" + format + "'"); } } if (-1 === [ 'P-256', 'P-384' ].indexOf(jwk.crv)) { throw new Error("options.jwk.crv must be either P-256 or P-384 for EC keys, not '" + jwk.crv + "'"); } if (!jwk.y) { throw new Error("options.jwk.y must be a urlsafe base64-encoded either P-256 or P-384"); } if ('sec1' === format) { return PEM.packBlock({ type: "EC PRIVATE KEY", bytes: x509.packSec1(jwk) }); } else if ('pkcs8' === format) { return PEM.packBlock({ type: "PRIVATE KEY", bytes: x509.packPkcs8(jwk) }); } else if (-1 !== [ 'spki', 'pkix' ].indexOf(format)) { return PEM.packBlock({ type: "PUBLIC KEY", bytes: x509.packSpki(jwk) }); } else if (-1 !== [ 'ssh', 'rfc4716' ].indexOf(format)) { return SSH.packSsh(jwk); } else { throw new Error("Sanity Error: reached unreachable code block with format: " + format); } }); }; EC.pack = function (opts) { return Promise.resolve().then(function () { return EC.exportSync(opts); }); }; // 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. EC.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 EC private parts if ('d' === k) { return; } jwk[k] = JSON.parse(JSON.stringify(opts.jwk[k])); }); return jwk; }; // https://stackoverflow.com/questions/42588786/how-to-fingerprint-a-jwk EC.__thumbprint = function (jwk) { // Use the same entropy for SHA as for key var alg = 'SHA-256'; if (/384/.test(jwk.crv)) { alg = 'SHA-384'; } return window.crypto.subtle.digest( { name: alg } , textEncoder.encode('{"crv":"' + jwk.crv + '","kty":"EC","x":"' + jwk.x + '","y":"' + jwk.y + '"}') ).then(function (hash) { return Enc.bufToUrlBase64(new Uint8Array(hash)); }); }; EC.thumbprint = function (opts) { return Promise.resolve().then(function () { var jwk; if ('EC' === opts.kty) { jwk = opts; } else if (opts.jwk) { jwk = opts.jwk; } else { return EC.import(opts).then(function (jwk) { return EC.__thumbprint(jwk); }); } return EC.__thumbprint(jwk); }); }; Enc.bufToUrlBase64 = function (u8) { return Enc.bufToBase64(u8) .replace(/\+/g, '-').replace(/\//g, '_').replace(/=/g, ''); }; Enc.bufToBase64 = function (u8) { var bin = ''; u8.forEach(function (i) { bin += String.fromCharCode(i); }); return btoa(bin); }; }('undefined' !== typeof module ? module.exports : window)); /*global Promise*/ (function (exports) { 'use strict'; var RSA = exports.Rasha = {}; var x509 = exports.x509; if ('undefined' !== typeof module) { module.exports = RSA; } var PEM = exports.PEM; var SSH = exports.SSH; var Enc = {}; var textEncoder = new TextEncoder(); RSA._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."; RSA._universal = "Bluecrypt only supports crypto with standard cross-browser and cross-platform support."; RSA.generate = function (opts) { var wcOpts = {}; if (!opts) { opts = {}; } if (!opts.kty) { opts.kty = 'RSA'; } // Support PSS? I don't think it's used for Let's Encrypt wcOpts.name = 'RSASSA-PKCS1-v1_5'; if (!opts.modulusLength) { opts.modulusLength = 2048; } wcOpts.modulusLength = opts.modulusLength; if (wcOpts.modulusLength >= 2048 && wcOpts.modulusLength < 3072) { // erring on the small side... for no good reason wcOpts.hash = { name: "SHA-256" }; } else if (wcOpts.modulusLength >= 3072 && wcOpts.modulusLength < 4096) { wcOpts.hash = { name: "SHA-384" }; } else if (wcOpts.modulusLength < 4097) { wcOpts.hash = { name: "SHA-512" }; } else { // Public key thumbprints should be paired with a hash of similar length, // so anything above SHA-512's keyspace would be left under-represented anyway. return Promise.Reject(new Error("'" + wcOpts.modulusLength + "' is not within the safe and universally" + " acceptable range of 2048-4096. Typically you should pick 2048, 3072, or 4096, though other values" + " divisible by 8 are allowed. " + RSA._stance)); } // TODO maybe allow this to be set to any of the standard values? wcOpts.publicExponent = new Uint8Array([0x01, 0x00, 0x01]); var extractable = true; return window.crypto.subtle.generateKey( wcOpts , extractable , [ 'sign', 'verify' ] ).then(function (result) { return window.crypto.subtle.exportKey( "jwk" , result.privateKey ).then(function (privJwk) { return { private: privJwk , public: RSA.neuter({ jwk: privJwk }) }; }); }); }; // 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. RSA.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 private parts if (-1 !== ['d', 'p', 'q', 'dp', 'dq', 'qi'].indexOf(k)) { return; } jwk[k] = JSON.parse(JSON.stringify(opts.jwk[k])); }); return jwk; }; // https://stackoverflow.com/questions/42588786/how-to-fingerprint-a-jwk RSA.__thumbprint = function (jwk) { // Use the same entropy for SHA as for key var len = Math.floor(jwk.n.length * 0.75); var alg = 'SHA-256'; // TODO this may be a bug // need to confirm that the padding is no more or less than 1 byte if (len >= 511) { alg = 'SHA-512'; } else if (len >= 383) { alg = 'SHA-384'; } return window.crypto.subtle.digest( { name: alg } , textEncoder.encode('{"e":"' + jwk.e + '","kty":"RSA","n":"' + jwk.n + '"}') ).then(function (hash) { return Enc.bufToUrlBase64(new Uint8Array(hash)); }); }; RSA.thumbprint = function (opts) { return Promise.resolve().then(function () { var jwk; if ('EC' === opts.kty) { jwk = opts; } else if (opts.jwk) { jwk = opts.jwk; } else { return RSA.import(opts).then(function (jwk) { return RSA.__thumbprint(jwk); }); } return RSA.__thumbprint(jwk); }); }; RSA.export = function (opts) { return Promise.resolve().then(function () { if (!opts || !opts.jwk || 'object' !== typeof opts.jwk) { throw new Error("must pass { jwk: jwk }"); } var jwk = JSON.parse(JSON.stringify(opts.jwk)); var format = opts.format; var pub = opts.public; if (pub || -1 !== [ 'spki', 'pkix', 'ssh', 'rfc4716' ].indexOf(format)) { jwk = RSA.neuter({ jwk: jwk }); } if ('RSA' !== jwk.kty) { throw new Error("options.jwk.kty must be 'RSA' for RSA keys"); } if (!jwk.p) { // TODO test for n and e pub = true; if (!format || 'pkcs1' === format) { format = 'pkcs1'; } else if (-1 !== [ 'spki', 'pkix' ].indexOf(format)) { format = 'spki'; } else if (-1 !== [ 'ssh', 'rfc4716' ].indexOf(format)) { format = 'ssh'; } else { throw new Error("options.format must be 'spki', 'pkcs1', or 'ssh' for public RSA keys, not (" + typeof format + ") " + format); } } else { // TODO test for all necessary keys (d, p, q ...) if (!format || 'pkcs1' === format) { format = 'pkcs1'; } else if ('pkcs8' !== format) { throw new Error("options.format must be 'pkcs1' or 'pkcs8' for private RSA keys"); } } if ('pkcs1' === format) { if (jwk.d) { return PEM.packBlock({ type: "RSA PRIVATE KEY", bytes: x509.packPkcs1(jwk) }); } else { return PEM.packBlock({ type: "RSA PUBLIC KEY", bytes: x509.packPkcs1(jwk) }); } } else if ('pkcs8' === format) { return PEM.packBlock({ type: "PRIVATE KEY", bytes: x509.packPkcs8(jwk) }); } else if (-1 !== [ 'spki', 'pkix' ].indexOf(format)) { return PEM.packBlock({ type: "PUBLIC KEY", bytes: x509.packSpki(jwk) }); } else if (-1 !== [ 'ssh', 'rfc4716' ].indexOf(format)) { return SSH.pack({ jwk: jwk, comment: opts.comment }); } else { throw new Error("Sanity Error: reached unreachable code block with format: " + format); } }); }; RSA.pack = function (opts) { // wrapped in a promise for API compatibility // with the forthcoming browser version // (and potential future native node capability) return Promise.resolve().then(function () { return RSA.export(opts); }); }; Enc.bufToUrlBase64 = function (u8) { return Enc.bufToBase64(u8) .replace(/\+/g, '-').replace(/\//g, '_').replace(/=/g, ''); }; Enc.bufToBase64 = function (u8) { var bin = ''; u8.forEach(function (i) { bin += String.fromCharCode(i); }); return btoa(bin); }; }('undefined' !== typeof module ? module.exports : window)); /*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) }; 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|asn1/i.test(opts.format)) { return Keypairs._ecdsaJoseSigToAsn1Sig(signature); } else { // jose/jws/jwt 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; 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.length], 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)); // Copyright 2018 AJ ONeal. All rights reserved /* 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/. */ ;(function (exports) { 'use strict'; if (!exports.ASN1) { exports.ASN1 = {}; } if (!exports.Enc) { exports.Enc = {}; } if (!exports.PEM) { exports.PEM = {}; } var ASN1 = exports.ASN1; var Enc = exports.Enc; var PEM = exports.PEM; // // Parser // // Although I've only seen 9 max in https certificates themselves, // but each domain list could have up to 100 ASN1.ELOOPN = 102; ASN1.ELOOP = "uASN1.js Error: iterated over " + ASN1.ELOOPN + "+ elements (probably a malformed file)"; // I've seen https certificates go 29 deep ASN1.EDEEPN = 60; ASN1.EDEEP = "uASN1.js Error: element nested " + ASN1.EDEEPN + "+ layers deep (probably a malformed file)"; // Container Types are Sequence 0x30, Container Array? (0xA0, 0xA1) // Value Types are Boolean 0x01, Integer 0x02, Null 0x05, Object ID 0x06, String 0x0C, 0x16, 0x13, 0x1e Value Array? (0x82) // Bit String (0x03) and Octet String (0x04) may be values or containers // Sometimes Bit String is used as a container (RSA Pub Spki) ASN1.CTYPES = [ 0x30, 0x31, 0xa0, 0xa1 ]; ASN1.VTYPES = [ 0x01, 0x02, 0x05, 0x06, 0x0c, 0x82 ]; ASN1.parse = function parseAsn1Helper(buf) { //var ws = ' '; function parseAsn1(buf, depth, eager) { if (depth.length >= ASN1.EDEEPN) { throw new Error(ASN1.EDEEP); } var index = 2; // we know, at minimum, data starts after type (0) and lengthSize (1) var asn1 = { type: buf[0], lengthSize: 0, length: buf[1] }; var child; var iters = 0; var adjust = 0; var adjustedLen; // Determine how many bytes the length uses, and what it is if (0x80 & asn1.length) { asn1.lengthSize = 0x7f & asn1.length; // I think that buf->hex->int solves the problem of Endianness... not sure asn1.length = parseInt(Enc.bufToHex(buf.slice(index, index + asn1.lengthSize)), 16); index += asn1.lengthSize; } // High-order bit Integers have a leading 0x00 to signify that they are positive. // Bit Streams use the first byte to signify padding, which x.509 doesn't use. if (0x00 === buf[index] && (0x02 === asn1.type || 0x03 === asn1.type)) { // However, 0x00 on its own is a valid number if (asn1.length > 1) { index += 1; adjust = -1; } } adjustedLen = asn1.length + adjust; //console.warn(depth.join(ws) + '0x' + Enc.numToHex(asn1.type), index, 'len:', asn1.length, asn1); function parseChildren(eager) { asn1.children = []; //console.warn('1 len:', (2 + asn1.lengthSize + asn1.length), 'idx:', index, 'clen:', 0); while (iters < ASN1.ELOOPN && index < (2 + asn1.length + asn1.lengthSize)) { iters += 1; depth.length += 1; child = parseAsn1(buf.slice(index, index + adjustedLen), depth, eager); depth.length -= 1; // The numbers don't match up exactly and I don't remember why... // probably something with adjustedLen or some such, but the tests pass index += (2 + child.lengthSize + child.length); //console.warn('2 len:', (2 + asn1.lengthSize + asn1.length), 'idx:', index, 'clen:', (2 + child.lengthSize + child.length)); if (index > (2 + asn1.lengthSize + asn1.length)) { if (!eager) { console.error(JSON.stringify(asn1, ASN1._replacer, 2)); } throw new Error("Parse error: child value length (" + child.length + ") is greater than remaining parent length (" + (asn1.length - index) + " = " + asn1.length + " - " + index + ")"); } asn1.children.push(child); //console.warn(depth.join(ws) + '0x' + Enc.numToHex(asn1.type), index, 'len:', asn1.length, asn1); } if (index !== (2 + asn1.lengthSize + asn1.length)) { //console.warn('index:', index, 'length:', (2 + asn1.lengthSize + asn1.length)); throw new Error("premature end-of-file"); } if (iters >= ASN1.ELOOPN) { throw new Error(ASN1.ELOOP); } delete asn1.value; return asn1; } // Recurse into types that are _always_ containers if (-1 !== ASN1.CTYPES.indexOf(asn1.type)) { return parseChildren(eager); } // Return types that are _always_ values asn1.value = buf.slice(index, index + adjustedLen); if (-1 !== ASN1.VTYPES.indexOf(asn1.type)) { return asn1; } // For ambigious / unknown types, recurse and return on failure // (and return child array size to zero) try { return parseChildren(true); } catch(e) { asn1.children.length = 0; return asn1; } } var asn1 = parseAsn1(buf, []); var len = buf.byteLength || buf.length; if (len !== 2 + asn1.lengthSize + asn1.length) { throw new Error("Length of buffer does not match length of ASN.1 sequence."); } return asn1; }; ASN1._replacer = function (k, v) { if ('type' === k) { return '0x' + Enc.numToHex(v); } if (v && 'value' === k) { return '0x' + Enc.bufToHex(v.data || v); } return v; }; // don't replace the full parseBlock, if it exists PEM.parseBlock = PEM.parseBlock || function (str) { var der = str.split(/\n/).filter(function (line) { return !/-----/.test(line); }).join(''); return { bytes: Enc.base64ToBuf(der) }; }; Enc.base64ToBuf = function (b64) { return Enc.binToBuf(atob(b64)); }; Enc.binToBuf = function (bin) { var arr = bin.split('').map(function (ch) { return ch.charCodeAt(0); }); return 'undefined' !== typeof Uint8Array ? new Uint8Array(arr) : arr; }; Enc.bufToHex = function (u8) { var hex = []; var i, h; var len = (u8.byteLength || u8.length); for (i = 0; i < len; i += 1) { h = u8[i].toString(16); if (h.length % 2) { h = '0' + h; } hex.push(h); } return hex.join('').toLowerCase(); }; Enc.numToHex = function (d) { d = d.toString(16); if (d.length % 2) { return '0' + d; } return d; }; }('undefined' !== typeof window ? window : module.exports)); // Copyright 2018-present AJ ONeal. All rights reserved /* 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/. */ (function (exports) { 'use strict'; /*global Promise*/ var ASN1 = exports.ASN1; var Enc = exports.Enc; var PEM = exports.PEM; var X509 = exports.x509; var Keypairs = exports.Keypairs; // TODO find a way that the prior node-ish way of `module.exports = function () {}` isn't broken var CSR = exports.CSR = function (opts) { // We're using a Promise here to be compatible with the browser version // which will probably use the webcrypto API for some of the conversions return CSR._prepare(opts).then(function (opts) { return CSR.create(opts).then(function (bytes) { return CSR._encode(opts, bytes); }); }); }; CSR._prepare = function (opts) { return Promise.resolve().then(function () { var Keypairs; opts = JSON.parse(JSON.stringify(opts)); // We do a bit of extra error checking for user convenience if (!opts) { throw new Error("You must pass options with key and domains to rsacsr"); } if (!Array.isArray(opts.domains) || 0 === opts.domains.length) { new Error("You must pass options.domains as a non-empty array"); } // I need to check that 例.中国 is a valid domain name if (!opts.domains.every(function (d) { // allow punycode? xn-- if ('string' === typeof d /*&& /\./.test(d) && !/--/.test(d)*/) { return true; } })) { throw new Error("You must pass options.domains as strings"); } if (opts.jwk) { return opts; } if (opts.key && opts.key.kty) { opts.jwk = opts.key; return opts; } if (!opts.pem && !opts.key) { throw new Error("You must pass options.key as a JSON web key"); } Keypairs = exports.Keypairs; if (!exports.Keypairs) { throw new Error("Keypairs.js is an optional dependency for PEM-to-JWK.\n" + "Install it if you'd like to use it:\n" + "\tnpm install --save rasha\n" + "Otherwise supply a jwk as the private key." ); } return Keypairs.import({ pem: opts.pem || opts.key }).then(function (pair) { opts.jwk = pair.private; return opts; }); }); }; CSR._encode = function (opts, bytes) { if ('der' === (opts.encoding||'').toLowerCase()) { return bytes; } return PEM.packBlock({ type: "CERTIFICATE REQUEST" , bytes: bytes /* { jwk: jwk, domains: opts.domains } */ }); }; CSR.create = function createCsr(opts) { var hex = CSR.request(opts.jwk, opts.domains); return CSR._sign(opts.jwk, hex).then(function (csr) { return Enc.hexToBuf(csr); }); }; // // EC / RSA // CSR.request = function createCsrBodyEc(jwk, domains) { var asn1pub; if (/^EC/i.test(jwk.kty)) { asn1pub = X509.packCsrEcPublicKey(jwk); } else { asn1pub = X509.packCsrRsaPublicKey(jwk); } return X509.packCsr(asn1pub, domains); }; CSR._sign = function csrEcSig(jwk, request) { // Took some tips from https://gist.github.com/codermapuche/da4f96cdb6d5ff53b7ebc156ec46a10a // TODO will have to convert web ECDSA signatures to PEM ECDSA signatures (but RSA should be the same) // TODO have a consistent non-private way to sign return Keypairs._sign({ jwk: jwk, format: 'x509' }, Enc.hexToBuf(request)).then(function (sig) { return CSR._toDer({ request: request, signature: sig, kty: jwk.kty }); }); }; CSR._toDer = function encode(opts) { var sty; if (/^EC/i.test(opts.kty)) { // 1.2.840.10045.4.3.2 ecdsaWithSHA256 (ANSI X9.62 ECDSA algorithm with SHA256) sty = ASN1('30', ASN1('06', '2a8648ce3d040302')); } else { // 1.2.840.113549.1.1.11 sha256WithRSAEncryption (PKCS #1) sty = ASN1('30', ASN1('06', '2a864886f70d01010b'), ASN1('05')); } return ASN1('30' // The Full CSR Request Body , opts.request // The Signature Type , sty // The Signature , ASN1.BitStr(Enc.bufToHex(opts.signature)) ); }; X509.packCsr = function (asn1pubkey, domains) { return ASN1('30' // Version (0) , ASN1.UInt('00') // 2.5.4.3 commonName (X.520 DN component) , ASN1('30', ASN1('31', ASN1('30', ASN1('06', '550403'), ASN1('0c', Enc.utf8ToHex(domains[0]))))) // Public Key (RSA or EC) , asn1pubkey // Request Body , ASN1('a0' , ASN1('30' // 1.2.840.113549.1.9.14 extensionRequest (PKCS #9 via CRMF) , ASN1('06', '2a864886f70d01090e') , ASN1('31' , ASN1('30' , ASN1('30' // 2.5.29.17 subjectAltName (X.509 extension) , ASN1('06', '551d11') , ASN1('04' , ASN1('30', domains.map(function (d) { return ASN1('82', Enc.utf8ToHex(d)); }).join('')))))))) ); }; // TODO finish this later // we want to parse the domains, the public key, and verify the signature CSR._info = function (der) { // standard base64 PEM if ('string' === typeof der && '-' === der[0]) { der = PEM.parseBlock(der).bytes; } // jose urlBase64 not-PEM if ('string' === typeof der) { der = Enc.base64ToBuf(der); } // not supporting binary-encoded bas64 var c = ASN1.parse(der); var kty; // A cert has 3 parts: cert, signature meta, signature if (c.children.length !== 3) { throw new Error("doesn't look like a certificate request: expected 3 parts of header"); } var sig = c.children[2]; if (sig.children.length) { // ASN1/X509 EC sig = sig.children[0]; sig = ASN1('30', ASN1.UInt(Enc.bufToHex(sig.children[0].value)), ASN1.UInt(Enc.bufToHex(sig.children[1].value))); sig = Enc.hexToBuf(sig); kty = 'EC'; } else { // Raw RSA Sig sig = sig.value; kty = 'RSA'; } //c.children[1]; // signature type var req = c.children[0]; // TODO utf8 if (4 !== req.children.length) { throw new Error("doesn't look like a certificate request: expected 4 parts to request"); } // 0 null // 1 commonName / subject var sub = Enc.bufToBin(req.children[1].children[0].children[0].children[1].value); // 3 public key (type, key) //console.log('oid', Enc.bufToHex(req.children[2].children[0].children[0].value)); var pub; // TODO reuse ASN1 parser for these? if ('EC' === kty) { // throw away compression byte pub = req.children[2].children[1].value.slice(1); pub = { kty: kty, x: pub.slice(0, 32), y: pub.slice(32) }; while (0 === pub.x[0]) { pub.x = pub.x.slice(1); } while (0 === pub.y[0]) { pub.y = pub.y.slice(1); } if ((pub.x.length || pub.x.byteLength) > 48) { pub.crv = 'P-521'; } else if ((pub.x.length || pub.x.byteLength) > 32) { pub.crv = 'P-384'; } else { pub.crv = 'P-256'; } pub.x = Enc.bufToUrlBase64(pub.x); pub.y = Enc.bufToUrlBase64(pub.y); } else { pub = req.children[2].children[1].children[0]; pub = { kty: kty, n: pub.children[0].value, e: pub.children[1].value }; while (0 === pub.n[0]) { pub.n = pub.n.slice(1); } while (0 === pub.e[0]) { pub.e = pub.e.slice(1); } pub.n = Enc.bufToUrlBase64(pub.n); pub.e = Enc.bufToUrlBase64(pub.e); } // 4 extensions var domains = req.children[3].children.filter(function (seq) { // 1.2.840.113549.1.9.14 extensionRequest (PKCS #9 via CRMF) if ('2a864886f70d01090e' === Enc.bufToHex(seq.children[0].value)) { return true; } }).map(function (seq) { return seq.children[1].children[0].children.filter(function (seq2) { // subjectAltName (X.509 extension) if ('551d11' === Enc.bufToHex(seq2.children[0].value)) { return true; } }).map(function (seq2) { return seq2.children[1].children[0].children.map(function (name) { // TODO utf8 return Enc.bufToBin(name.value); }); })[0]; })[0]; return { subject: sub , altnames: domains , jwk: pub , signature: sig }; }; X509.packCsrRsaPublicKey = function (jwk) { // Sequence the key var n = ASN1.UInt(Enc.base64ToHex(jwk.n)); var e = ASN1.UInt(Enc.base64ToHex(jwk.e)); var asn1pub = ASN1('30', n, e); // Add the CSR pub key header return ASN1('30', ASN1('30', ASN1('06', '2a864886f70d010101'), ASN1('05')), ASN1.BitStr(asn1pub)); }; X509.packCsrEcPublicKey = function (jwk) { var ecOid = X509._oids[jwk.crv]; if (!ecOid) { throw new Error("Unsupported namedCurve '" + jwk.crv + "'. Supported types are " + Object.keys(X509._oids)); } var cmp = '04'; // 04 == x+y, 02 == x-only var hxy = ''; // Placeholder. I'm not even sure if compression should be supported. if (!jwk.y) { cmp = '02'; } hxy += Enc.base64ToHex(jwk.x); if (jwk.y) { hxy += Enc.base64ToHex(jwk.y); } // 1.2.840.10045.2.1 ecPublicKey return ASN1('30', ASN1('30', ASN1('06', '2a8648ce3d0201'), ASN1('06', ecOid)), ASN1.BitStr(cmp + hxy)); }; X509._oids = { // 1.2.840.10045.3.1.7 prime256v1 // (ANSI X9.62 named elliptic curve) (06 08 - 2A 86 48 CE 3D 03 01 07) 'P-256': '2a8648ce3d030107' // 1.3.132.0.34 P-384 (06 05 - 2B 81 04 00 22) // (SEC 2 recommended EC domain secp256r1) , 'P-384': '2b81040022' // requires more logic and isn't a recommended standard // 1.3.132.0.35 P-521 (06 05 - 2B 81 04 00 23) // (SEC 2 alternate P-521) //, 'P-521': '2B 81 04 00 23' }; // don't replace the full parseBlock, if it exists PEM.parseBlock = PEM.parseBlock || function (str) { var der = str.split(/\n/).filter(function (line) { return !/-----/.test(line); }).join(''); return { bytes: Enc.base64ToBuf(der) }; }; }('undefined' === typeof window ? module.exports : window)); // Copyright 2018-present AJ ONeal. All rights reserved /* 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/. */ (function (exports) { 'use strict'; /* globals Promise */ var ACME = exports.ACME = {}; //var Keypairs = exports.Keypairs || {}; //var CSR = exports.CSR; var Enc = exports.Enc || {}; var Crypto = exports.Crypto || {}; ACME.formatPemChain = function formatPemChain(str) { return str.trim().replace(/[\r\n]+/g, '\n').replace(/\-\n\-/g, '-\n\n-') + '\n'; }; ACME.splitPemChain = function splitPemChain(str) { return str.trim().split(/[\r\n]{2,}/g).map(function (str) { return str + '\n'; }); }; // http-01: GET https://example.org/.well-known/acme-challenge/{{token}} => {{keyAuth}} // dns-01: TXT _acme-challenge.example.org. => "{{urlSafeBase64(sha256(keyAuth))}}" ACME.challengePrefixes = { 'http-01': '/.well-known/acme-challenge' , 'dns-01': '_acme-challenge' }; ACME.challengeTests = { 'http-01': function (me, auth) { return me.http01(auth).then(function (keyAuth) { var err; // TODO limit the number of bytes that are allowed to be downloaded if (auth.keyAuthorization === (keyAuth||'').trim()) { return true; } err = new Error( "Error: Failed HTTP-01 Pre-Flight / Dry Run.\n" + "curl '" + auth.challengeUrl + "'\n" + "Expected: '" + auth.keyAuthorization + "'\n" + "Got: '" + keyAuth + "'\n" + "See https://git.coolaj86.com/coolaj86/acme-v2.js/issues/4" ); err.code = 'E_FAIL_DRY_CHALLENGE'; return Promise.reject(err); }); } , 'dns-01': function (me, auth) { // remove leading *. on wildcard domains return me.dns01(auth).then(function (ans) { var err; if (ans.answer.some(function (txt) { return auth.dnsAuthorization === txt.data[0]; })) { return true; } err = new Error( "Error: Failed DNS-01 Pre-Flight Dry Run.\n" + "dig TXT '" + auth.dnsHost + "' does not return '" + auth.dnsAuthorization + "'\n" + "See https://git.coolaj86.com/coolaj86/acme-v2.js/issues/4" ); err.code = 'E_FAIL_DRY_CHALLENGE'; return Promise.reject(err); }); } }; ACME._directory = function (me) { // GET-as-GET ok return me.request({ method: 'GET', url: me.directoryUrl, json: true }); }; ACME._getNonce = function (me) { // GET-as-GET, HEAD-as-HEAD ok var nonce; while (true) { nonce = me._nonces.shift(); if (!nonce) { break; } if (Date.now() - nonce.createdAt > (15 * 60 * 1000)) { nonce = null; } else { break; } } if (nonce) { return Promise.resolve(nonce.nonce); } return me.request({ method: 'HEAD', url: me._directoryUrls.newNonce }).then(function (resp) { return resp.headers['replay-nonce']; }); }; ACME._setNonce = function (me, nonce) { me._nonces.unshift({ nonce: nonce, createdAt: Date.now() }); }; // ACME RFC Section 7.3 Account Creation /* { "protected": base64url({ "alg": "ES256", "jwk": {...}, "nonce": "6S8IqOGY7eL2lsGoTZYifg", "url": "https://example.com/acme/new-account" }), "payload": base64url({ "termsOfServiceAgreed": true, "onlyReturnExisting": false, "contact": [ "mailto:cert-admin@example.com", "mailto:admin@example.com" ] }), "signature": "RZPOnYoPs1PhjszF...-nh6X1qtOFPB519I" } */ ACME._registerAccount = function (me, options) { if (me.debug) { console.debug('[acme-v2] accounts.create'); } return new Promise(function (resolve, reject) { function agree(tosUrl) { var err; if (me._tos !== tosUrl) { err = new Error("You must agree to the ToS at '" + me._tos + "'"); err.code = "E_AGREE_TOS"; reject(err); return; } return ACME._importKeypair(me, options.accountKeypair).then(function (pair) { var contact; if (options.contact) { contact = options.contact.slice(0); } else if (options.email) { contact = [ 'mailto:' + options.email ]; } var body = { termsOfServiceAgreed: tosUrl === me._tos , onlyReturnExisting: false , contact: contact }; var pExt; if (options.externalAccount) { pExt = me.Keypairs.signJws({ // TODO is HMAC the standard, or is this arbitrary? secret: options.externalAccount.secret , protected: { alg: options.externalAccount.alg || "HS256" , kid: options.externalAccount.id , url: me._directoryUrls.newAccount } , payload: Enc.binToBuf(JSON.stringify(pair.public)) }).then(function (jws) { body.externalAccountBinding = jws; return body; }); } else { pExt = Promise.resolve(body); } return pExt.then(function (body) { var payload = JSON.stringify(body); return ACME._jwsRequest(me, { options: options , url: me._directoryUrls.newAccount , protected: { kid: false, jwk: pair.public } , payload: Enc.binToBuf(payload) }).then(function (resp) { var account = resp.body; if (2 !== Math.floor(resp.statusCode / 100)) { throw new Error('account error: ' + JSON.stringify(resp.body)); } var location = resp.headers.location; // the account id url options._kid = location; if (me.debug) { console.debug('[DEBUG] new account location:'); } if (me.debug) { console.debug(location); } if (me.debug) { console.debug(resp); } /* { contact: ["mailto:jon@example.com"], orders: "https://some-url", status: 'valid' } */ if (!account) { account = { _emptyResponse: true }; } // https://git.coolaj86.com/coolaj86/acme-v2.js/issues/8 if (!account.key) { account.key = {}; } account.key.kid = options._kid; return account; }).then(resolve, reject); }); }); } if (me.debug) { console.debug('[acme-v2] agreeToTerms'); } if (1 === options.agreeToTerms.length) { // newer promise API return Promise.resolve(options.agreeToTerms(me._tos)).then(agree, reject); } else if (2 === options.agreeToTerms.length) { // backwards compat cb API return options.agreeToTerms(me._tos, function (err, tosUrl) { if (!err) { agree(tosUrl); return; } reject(err); }); } else { reject(new Error('agreeToTerms has incorrect function signature.' + ' Should be fn(tos) { return Promise; }')); } }); }; /* POST /acme/new-order HTTP/1.1 Host: example.com Content-Type: application/jose+json { "protected": base64url({ "alg": "ES256", "kid": "https://example.com/acme/acct/1", "nonce": "5XJ1L3lEkMG7tR6pA00clA", "url": "https://example.com/acme/new-order" }), "payload": base64url({ "identifiers": [{"type:"dns","value":"example.com"}], "notBefore": "2016-01-01T00:00:00Z", "notAfter": "2016-01-08T00:00:00Z" }), "signature": "H6ZXtGjTZyUnPeKn...wEA4TklBdh3e454g" } */ ACME._getChallenges = function (me, options, authUrl) { if (me.debug) { console.debug('\n[DEBUG] getChallenges\n'); } // TODO POST-as-GET return ACME._jwsRequest(me, { options: options , protected: {} , payload: '' , url: authUrl }).then(function (resp) { return resp.body; }); }; ACME._wait = function wait(ms) { return new Promise(function (resolve) { setTimeout(resolve, (ms || 1100)); }); }; ACME._testChallengeOptions = function () { var chToken = ACME._prnd(16); return [ { "type": "http-01", "status": "pending", "url": "https://acme-staging-v02.example.com/0", "token": "test-" + chToken + "-0" } , { "type": "dns-01", "status": "pending", "url": "https://acme-staging-v02.example.com/1", "token": "test-" + chToken + "-1", "_wildcard": true } , { "type": "tls-sni-01", "status": "pending", "url": "https://acme-staging-v02.example.com/2", "token": "test-" + chToken + "-2" } , { "type": "tls-alpn-01", "status": "pending", "url": "https://acme-staging-v02.example.com/3", "token": "test-" + chToken + "-3" } ]; }; ACME._testChallenges = function (me, options) { var CHECK_DELAY = 0; return Promise.all(options.domains.map(function (identifierValue) { // TODO we really only need one to pass, not all to pass var challenges = ACME._testChallengeOptions(); if (identifierValue.includes("*")) { challenges = challenges.filter(function (ch) { return ch._wildcard; }); } var challenge = ACME._chooseChallenge(options, { challenges: challenges }); if (!challenge) { // For example, wildcards require dns-01 and, if we don't have that, we have to bail var enabled = options.challengeTypes.join(', ') || 'none'; var suitable = challenges.map(function (r) { return r.type; }).join(', ') || 'none'; return Promise.reject(new Error( "None of the challenge types that you've enabled ( " + enabled + " )" + " are suitable for validating the domain you've selected (" + identifierValue + ")." + " You must enable one of ( " + suitable + " )." )); } // TODO remove skipChallengeTest if (me.skipDryRun || me.skipChallengeTest) { return null; } if ('dns-01' === challenge.type) { // Give the nameservers a moment to propagate CHECK_DELAY = 1.5 * 1000; } return Promise.resolve().then(function () { var results = { identifier: { type: "dns" , value: identifierValue.replace(/^\*\./, '') } , challenges: [ challenge ] , expires: new Date(Date.now() + (60 * 1000)).toISOString() , wildcard: identifierValue.includes('*.') || undefined }; // The dry-run comes first in the spirit of "fail fast" // (and protecting against challenge failure rate limits) var dryrun = true; return ACME._challengeToAuth(me, options, results, challenge, dryrun).then(function (auth) { if (!me._canUse[auth.type]) { return; } return ACME._setChallenge(me, options, auth).then(function () { return auth; }); }); }); })).then(function (auths) { auths = auths.filter(Boolean); if (!auths.length) { /*skip actual test*/ return; } return ACME._wait(CHECK_DELAY).then(function () { return Promise.all(auths.map(function (auth) { return ACME.challengeTests[auth.type](me, auth).then(function (result) { // not a blocker ACME._removeChallenge(me, options, auth); return result; }); })); }); }); }; ACME._chooseChallenge = function(options, results) { // For each of the challenge types that we support var challenge; options.challengeTypes.some(function (chType) { // And for each of the challenge types that are allowed return results.challenges.some(function (ch) { // Check to see if there are any matches if (ch.type === chType) { challenge = ch; return true; } }); }); return challenge; }; ACME._challengeToAuth = function (me, options, request, challenge, dryrun) { // we don't poison the dns cache with our dummy request var dnsPrefix = ACME.challengePrefixes['dns-01']; if (dryrun) { dnsPrefix = dnsPrefix.replace('acme-challenge', 'greenlock-dryrun-' + ACME._prnd(4)); } var auth = {}; // straight copy from the new order response // { identifier, status, expires, challenges, wildcard } Object.keys(request).forEach(function (key) { auth[key] = request[key]; }); // copy from the challenge we've chosen // { type, status, url, token } // (note the duplicate status overwrites the one above, but they should be the same) Object.keys(challenge).forEach(function (key) { // don't confused devs with the id url auth[key] = challenge[key]; }); // batteries-included helpers auth.hostname = auth.identifier.value; // because I'm not 100% clear if the wildcard identifier does or doesn't have the leading *. in all cases auth.altname = ACME._untame(auth.identifier.value, auth.wildcard); return ACME._importKeypair(me, options.accountKeypair).then(function (pair) { return me.Keypairs.thumbprint({ jwk: pair.public }).then(function (thumb) { auth.thumbprint = thumb; // keyAuthorization = token || '.' || base64url(JWK_Thumbprint(accountKey)) auth.keyAuthorization = challenge.token + '.' + auth.thumbprint; // conflicts with ACME challenge id url is already in use, so we call this challengeUrl instead // TODO auth.http01Url ? auth.challengeUrl = 'http://' + auth.identifier.value + ACME.challengePrefixes['http-01'] + '/' + auth.token; auth.dnsHost = dnsPrefix + '.' + auth.hostname.replace('*.', ''); return Crypto._sha('sha256', auth.keyAuthorization).then(function (hash) { auth.dnsAuthorization = hash; return auth; }); }); }); }; ACME._untame = function (name, wild) { if (wild) { name = '*.' + name.replace('*.', ''); } return name; }; // https://tools.ietf.org/html/draft-ietf-acme-acme-10#section-7.5.1 ACME._postChallenge = function (me, options, auth) { var RETRY_INTERVAL = me.retryInterval || 1000; var DEAUTH_INTERVAL = me.deauthWait || 10 * 1000; var MAX_POLL = me.retryPoll || 8; var MAX_PEND = me.retryPending || 4; var count = 0; var altname = ACME._untame(auth.identifier.value, auth.wildcard); /* POST /acme/authz/1234 HTTP/1.1 Host: example.com Content-Type: application/jose+json { "protected": base64url({ "alg": "ES256", "kid": "https://example.com/acme/acct/1", "nonce": "xWCM9lGbIyCgue8di6ueWQ", "url": "https://example.com/acme/authz/1234" }), "payload": base64url({ "status": "deactivated" }), "signature": "srX9Ji7Le9bjszhu...WTFdtujObzMtZcx4" } */ function deactivate() { if (me.debug) { console.debug('[acme-v2.js] deactivate:'); } return ACME._jwsRequest(me, { options: options , url: auth.url , protected: { kid: options._kid } , payload: Enc.binToBuf(JSON.stringify({ "status": "deactivated" })) }).then(function (resp) { if (me.debug) { console.debug('deactivate challenge: resp.body:'); } if (me.debug) { console.debug(resp.body); } return ACME._wait(DEAUTH_INTERVAL); }); } function pollStatus() { if (count >= MAX_POLL) { return Promise.reject(new Error( "[acme-v2] stuck in bad pending/processing state for '" + altname + "'" )); } count += 1; if (me.debug) { console.debug('\n[DEBUG] statusChallenge\n'); } // TODO POST-as-GET return me.request({ method: 'GET', url: auth.url, json: true }).then(function (resp) { if ('processing' === resp.body.status) { if (me.debug) { console.debug('poll: again'); } return ACME._wait(RETRY_INTERVAL).then(pollStatus); } // This state should never occur if ('pending' === resp.body.status) { if (count >= MAX_PEND) { return ACME._wait(RETRY_INTERVAL).then(deactivate).then(respondToChallenge); } if (me.debug) { console.debug('poll: again'); } return ACME._wait(RETRY_INTERVAL).then(respondToChallenge); } if ('valid' === resp.body.status) { if (me.debug) { console.debug('poll: valid'); } try { ACME._removeChallenge(me, options, auth); } catch(e) {} return resp.body; } var errmsg; if (!resp.body.status) { errmsg = "[acme-v2] (E_STATE_EMPTY) empty challenge state for '" + altname + "':"; } else if ('invalid' === resp.body.status) { errmsg = "[acme-v2] (E_STATE_INVALID) challenge state for '" + altname + "': '" + resp.body.status + "'"; } else { errmsg = "[acme-v2] (E_STATE_UKN) challenge state for '" + altname + "': '" + resp.body.status + "'"; } return Promise.reject(new Error(errmsg)); }); } function respondToChallenge() { if (me.debug) { console.debug('[acme-v2.js] responding to accept challenge:'); } return ACME._jwsRequest(me, { options: options , url: auth.url , protected: { kid: options._kid } , payload: Enc.binToBuf(JSON.stringify({})) }).then(function (resp) { if (me.debug) { console.debug('respond to challenge: resp.body:'); } if (me.debug) { console.debug(resp.body); } return ACME._wait(RETRY_INTERVAL).then(pollStatus); }); } return respondToChallenge(); }; ACME._setChallenge = function (me, options, auth) { return new Promise(function (resolve, reject) { var challengers = options.challenges || {}; var challenger = (challengers[auth.type] && challengers[auth.type].set) || options.setChallenge; try { if (1 === challenger.length) { challenger(auth).then(resolve).catch(reject); } else if (2 === challenger.length) { challenger(auth, function (err) { if(err) { reject(err); } else { resolve(); } }); } else { // TODO remove this old backwards-compat var challengeCb = function(err) { if(err) { reject(err); } else { resolve(); } }; // for backwards compat adding extra keys without changing params length Object.keys(auth).forEach(function (key) { challengeCb[key] = auth[key]; }); if (!ACME._setChallengeWarn) { console.warn("Please update to acme-v2 setChallenge(options) or setChallenge(options, cb)."); console.warn("The API has been changed for compatibility with all ACME / Let's Encrypt challenge types."); ACME._setChallengeWarn = true; } challenger(auth.identifier.value, auth.token, auth.keyAuthorization, challengeCb); } } catch(e) { reject(e); } }).then(function () { // TODO: Do we still need this delay? Or shall we leave it to plugins to account for themselves? var DELAY = me.setChallengeWait || 500; if (me.debug) { console.debug('\n[DEBUG] waitChallengeDelay %s\n', DELAY); } return ACME._wait(DELAY); }); }; ACME._finalizeOrder = function (me, options, validatedDomains) { if (me.debug) { console.debug('finalizeOrder:'); } return ACME._generateCsrWeb64(me, options, validatedDomains).then(function (csr) { var body = { csr: csr }; var payload = JSON.stringify(body); function pollCert() { if (me.debug) { console.debug('[acme-v2.js] pollCert:'); } return ACME._jwsRequest(me, { options: options , url: options._finalize , protected: { kid: options._kid } , payload: Enc.binToBuf(payload) }).then(function (resp) { if (me.debug) { console.debug('order finalized: resp.body:'); } if (me.debug) { console.debug(resp.body); } // https://tools.ietf.org/html/draft-ietf-acme-acme-12#section-7.1.3 // Possible values are: "pending" => ("invalid" || "ready") => "processing" => "valid" if ('valid' === resp.body.status) { options._expires = resp.body.expires; options._certificate = resp.body.certificate; return resp.body; // return order } if ('processing' === resp.body.status) { return ACME._wait().then(pollCert); } if (me.debug) { console.debug("Error: bad status:\n" + JSON.stringify(resp.body, null, 2)); } if ('pending' === resp.body.status) { return Promise.reject(new Error( "Did not finalize order: status 'pending'." + " Best guess: You have not accepted at least one challenge for each domain:\n" + "Requested: '" + options.domains.join(', ') + "'\n" + "Validated: '" + validatedDomains.join(', ') + "'\n" + JSON.stringify(resp.body, null, 2) )); } if ('invalid' === resp.body.status) { return Promise.reject(new Error( "Did not finalize order: status 'invalid'." + " Best guess: One or more of the domain challenges could not be verified" + " (or the order was canceled).\n" + "Requested: '" + options.domains.join(', ') + "'\n" + "Validated: '" + validatedDomains.join(', ') + "'\n" + JSON.stringify(resp.body, null, 2) )); } if ('ready' === resp.body.status) { return Promise.reject(new Error( "Did not finalize order: status 'ready'." + " Hmmm... this state shouldn't be possible here. That was the last state." + " This one should at least be 'processing'.\n" + "Requested: '" + options.domains.join(', ') + "'\n" + "Validated: '" + validatedDomains.join(', ') + "'\n" + JSON.stringify(resp.body, null, 2) + "\n\n" + "Please open an issue at https://git.coolaj86.com/coolaj86/acme-v2.js" )); } return Promise.reject(new Error( "Didn't finalize order: Unhandled status '" + resp.body.status + "'." + " This is not one of the known statuses...\n" + "Requested: '" + options.domains.join(', ') + "'\n" + "Validated: '" + validatedDomains.join(', ') + "'\n" + JSON.stringify(resp.body, null, 2) + "\n\n" + "Please open an issue at https://git.coolaj86.com/coolaj86/acme-v2.js" )); }); } return pollCert(); }); }; // _kid // registerAccount // postChallenge // finalizeOrder // getCertificate ACME._getCertificate = function (me, options) { if (me.debug) { console.debug('[acme-v2] DEBUG get cert 1'); } // Lot's of error checking to inform the user of mistakes if (!(options.challengeTypes||[]).length) { options.challengeTypes = Object.keys(options.challenges||{}); } if (!options.challengeTypes.length) { options.challengeTypes = [ options.challengeType ].filter(Boolean); } if (options.challengeType) { options.challengeTypes.sort(function (a, b) { if (a === options.challengeType) { return -1; } if (b === options.challengeType) { return 1; } return 0; }); if (options.challengeType !== options.challengeTypes[0]) { return Promise.reject(new Error("options.challengeType is '" + options.challengeType + "'," + " which does not exist in the supplied types '" + options.challengeTypes.join(',') + "'")); } } // TODO check that all challengeTypes are represented in challenges if (!options.challengeTypes.length) { return Promise.reject(new Error("options.challengeTypes (string array) must be specified" + " (and in order of preferential priority).")); } if (options.csr) { // TODO validate csr signature options._csr = me.CSR._info(options.csr); options.domains = options._csr.altnames; if (options._csr.subject !== options.domains[0]) { return Promise.reject(new Error("certificate subject (commonName) does not match first altname (SAN)")); } } if (!(options.domains && options.domains.length)) { return Promise.reject(new Error("options.domains must be a list of string domain names," + " with the first being the subject of the certificate (or options.subject must specified).")); } // It's just fine if there's no account, we'll go get the key id we need via the existing key options._kid = options._kid || options.accountKid || (options.account && (options.account.kid || (options.account.key && options.account.key.kid))); if (!options._kid) { //return Promise.reject(new Error("must include KeyID")); // This is an idempotent request. It'll return the same account for the same public key. return ACME._registerAccount(me, options).then(function (account) { options._kid = account.key.kid; // start back from the top return ACME._getCertificate(me, options); }); } // Do a little dry-run / self-test return ACME._testChallenges(me, options).then(function () { if (me.debug) { console.debug('[acme-v2] certificates.create'); } var body = { // raw wildcard syntax MUST be used here identifiers: options.domains.sort(function (a, b) { // the first in the list will be the subject of the certificate, I believe (and hope) if (!options.subject) { return 0; } if (options.subject === a) { return -1; } if (options.subject === b) { return 1; } return 0; }).map(function (hostname) { return { type: "dns", value: hostname }; }) //, "notBefore": "2016-01-01T00:00:00Z" //, "notAfter": "2016-01-08T00:00:00Z" }; var payload = JSON.stringify(body); if (me.debug) { console.debug('\n[DEBUG] newOrder\n'); } return ACME._jwsRequest(me, { options: options , url: me._directoryUrls.newOrder , protected: { kid: options._kid } , payload: Enc.binToBuf(payload) }).then(function (resp) { var location = resp.headers.location; var setAuths; var validAuths = []; var auths = []; if (me.debug) { console.debug('[ordered]', location); } // the account id url if (me.debug) { console.debug(resp); } options._authorizations = resp.body.authorizations; options._order = location; options._finalize = resp.body.finalize; //if (me.debug) console.debug('[DEBUG] finalize:', options._finalize); return; if (!options._authorizations) { return Promise.reject(new Error( "[acme-v2.js] authorizations were not fetched for '" + options.domains.join() + "':\n" + JSON.stringify(resp.body) )); } if (me.debug) { console.debug("[acme-v2] POST newOrder has authorizations"); } setAuths = options._authorizations.slice(0); function setNext() { var authUrl = setAuths.shift(); if (!authUrl) { return; } return ACME._getChallenges(me, options, authUrl).then(function (results) { // var domain = options.domains[i]; // results.identifier.value // If it's already valid, we're golden it regardless if (results.challenges.some(function (ch) { return 'valid' === ch.status; })) { return setNext(); } var challenge = ACME._chooseChallenge(options, results); if (!challenge) { // For example, wildcards require dns-01 and, if we don't have that, we have to bail return Promise.reject(new Error( "Server didn't offer any challenge we can handle for '" + options.domains.join() + "'." )); } return ACME._challengeToAuth(me, options, results, challenge, false).then(function (auth) { auths.push(auth); return ACME._setChallenge(me, options, auth).then(setNext); }); }); } function checkNext() { var auth = auths.shift(); if (!auth) { return; } if (!me._canUse[auth.type] || me.skipChallengeTest) { // not so much "valid" as "not invalid" // but in this case we can't confirm either way validAuths.push(auth); return Promise.resolve(); } return ACME.challengeTests[auth.type](me, auth).then(function () { validAuths.push(auth); }).then(checkNext); } function challengeNext() { var auth = validAuths.shift(); if (!auth) { return; } return ACME._postChallenge(me, options, auth).then(challengeNext); } // First we set every challenge // Then we ask for each challenge to be checked // Doing otherwise would potentially cause us to poison our own DNS cache with misses return setNext().then(checkNext).then(challengeNext).then(function () { if (me.debug) { console.debug("[getCertificate] next.then"); } var validatedDomains = body.identifiers.map(function (ident) { return ident.value; }); return ACME._finalizeOrder(me, options, validatedDomains); }).then(function (order) { if (me.debug) { console.debug('acme-v2: order was finalized'); } // TODO POST-as-GET return me.request({ method: 'GET', url: options._certificate, json: true }).then(function (resp) { if (me.debug) { console.debug('acme-v2: csr submitted and cert received:'); } // https://github.com/certbot/certbot/issues/5721 var certsarr = ACME.splitPemChain(ACME.formatPemChain((resp.body||''))); // cert, chain, fullchain, privkey, /*TODO, subject, altnames, issuedAt, expiresAt */ var certs = { expires: order.expires , identifiers: order.identifiers //, authorizations: order.authorizations , cert: certsarr.shift() //, privkey: privkeyPem , chain: certsarr.join('\n') }; if (me.debug) { console.debug(certs); } return certs; }); }); }); }); }; ACME._generateCsrWeb64 = function (me, options, validatedDomains) { var csr; if (options.csr) { csr = options.csr; // if der, convert to base64 if ('string' !== typeof csr) { csr = Enc.bufToUrlBase64(csr); } // nix PEM headers, if any if ('-' === csr[0]) { csr = csr.split(/\n+/).slice(1, -1).join(''); } csr = Enc.base64ToUrlBase64(csr.trim().replace(/\s+/g, '')); return Promise.resolve(csr); } return ACME._importKeypair(me, options.serverKeypair || options.domainKeypair).then(function (pair) { return me.CSR({ jwk: pair.private, domains: validatedDomains, encoding: 'der' }).then(function (der) { return Enc.bufToUrlBase64(der); }); }); }; ACME.create = function create(me) { if (!me) { me = {}; } // me.debug = true; me.challengePrefixes = ACME.challengePrefixes; me.Keypairs = me.Keypairs || exports.Keypairs || require('keypairs').Keypairs; me.CSR = me.CSR || exports.CSR || require('CSR').CSR; me._nonces = []; me._canUse = {}; if (!me._baseUrl) { me._baseUrl = ""; } //me.Keypairs = me.Keypairs || require('keypairs'); //me.request = me.request || require('@root/request'); if (!me.dns01) { me.dns01 = function (auth) { return ACME._dns01(me, auth); }; } // backwards compat if (!me.dig) { me.dig = me.dns01; } if (!me.http01) { me.http01 = function (auth) { return ACME._http01(me, auth); }; } if ('function' !== typeof me.request) { me.request = ACME._defaultRequest; } me.init = function (opts) { function fin(dir) { me._directoryUrls = dir; me._tos = dir.meta.termsOfService; return dir; } if (opts && opts.meta && opts.termsOfService) { return Promise.resolve(fin(opts)); } if (!me.directoryUrl) { me.directoryUrl = opts; } if ('string' !== typeof me.directoryUrl) { throw new Error("you must supply either the ACME directory url as a string or an object of the ACME urls"); } var p = Promise.resolve(); if (!me.skipChallengeTest) { p = me.request({ url: me._baseUrl + "/api/_acme_api_/" }).then(function (resp) { if (resp.body.success) { me._canCheck['http-01'] = true; me._canCheck['dns-01'] = true; } }).catch(function () { // ignore }); } return p.then(function () { return ACME._directory(me).then(function (resp) { return fin(resp.body); }); }); }; me.accounts = { create: function (options) { return ACME._registerAccount(me, options); } }; me.certificates = { create: function (options) { return ACME._getCertificate(me, options); } }; return me; }; // Handle nonce, signing, and request altogether ACME._jwsRequest = function (me, bigopts) { return ACME._getNonce(me).then(function (nonce) { bigopts.protected.nonce = nonce; bigopts.protected.url = bigopts.url; // protected.alg: added by Keypairs.signJws if (!bigopts.protected.jwk) { // protected.kid must be overwritten due to ACME's interpretation of the spec if (!bigopts.protected.kid) { bigopts.protected.kid = bigopts.options._kid; } } return me.Keypairs.signJws( { jwk: bigopts.options.accountKeypair.privateKeyJwk , protected: bigopts.protected , payload: bigopts.payload } ).then(function (jws) { if (me.debug) { console.debug('[acme-v2] ' + bigopts.url + ':'); } if (me.debug) { console.debug(jws); } return ACME._request(me, { url: bigopts.url, json: jws }); }); }); }; // Handle some ACME-specific defaults ACME._request = function (me, opts) { if (!opts.headers) { opts.headers = {}; } if (opts.json && true !== opts.json) { opts.headers['Content-Type'] = 'application/jose+json'; opts.body = JSON.stringify(opts.json); if (!opts.method) { opts.method = 'POST'; } } return me.request(opts).then(function (resp) { resp = resp.toJSON(); if (resp.headers['replay-nonce']) { ACME._setNonce(me, resp.headers['replay-nonce']); } return resp; }); }; // A very generic, swappable request lib ACME._defaultRequest = function (opts) { // Note: normally we'd have to supply a User-Agent string, but not here in a browser if (!opts.headers) { opts.headers = {}; } if (opts.json) { opts.headers.Accept = 'application/json'; if (true !== opts.json) { opts.body = JSON.stringify(opts.json); } } if (!opts.method) { opts.method = 'GET'; if (opts.body) { opts.method = 'POST'; } } opts.cors = true; return window.fetch(opts.url, opts).then(function (resp) { var headers = {}; var result = { statusCode: resp.status, headers: headers, toJSON: function () { return this; } }; Array.from(resp.headers.entries()).forEach(function (h) { headers[h[0]] = h[1]; }); if (!headers['content-type']) { return result; } if (/json/.test(headers['content-type'])) { return resp.json().then(function (json) { result.body = json; return result; }); } return resp.text().then(function (txt) { result.body = txt; return result; }); }); }; ACME._importKeypair = function (me, kp) { var jwk = kp.privateKeyJwk; var p; if (jwk) { // nix the browser jwk extras jwk.key_ops = undefined; jwk.ext = undefined; p = Promise.resolve({ private: jwk, public: me.Keypairs.neuter({ jwk: jwk }) }); } else { p = me.Keypairs.import({ pem: kp.privateKeyPem }); } return p.then(function (pair) { kp.privateKeyJwk = pair.private; kp.publicKeyJwk = pair.public; if (pair.public.kid) { pair = JSON.parse(JSON.stringify(pair)); delete pair.public.kid; delete pair.private.kid; } return pair; }); }; /* TODO Per-Order State Params _kty _alg _finalize _expires _certificate _order _authorizations */ ACME._toWebsafeBase64 = function (b64) { return b64.replace(/\+/g, "-").replace(/\//g, "_").replace(/=/g,""); }; // In v8 this is crypto random, but we're just using it for pseudorandom ACME._prnd = function (n) { var rnd = ''; while (rnd.length / 2 < n) { var num = Math.random().toString().substr(2); if (num.length % 2) { num = '0' + num; } var pairs = num.match(/(..?)/g); rnd += pairs.map(ACME._toHex).join(''); } return rnd.substr(0, n*2); }; ACME._toHex = function (pair) { return parseInt(pair, 10).toString(16); }; ACME._dns01 = function (me, auth) { return new me.request({ url: me._baseUrl + "/api/dns/" + auth.dnsHost + "?type=TXT" }).then(function (resp) { var err; if (!resp.body || !Array.isArray(resp.body.answer)) { err = new Error("failed to get DNS response"); console.error(err); throw err; } if (!resp.body.answer.length) { err = new Error("failed to get DNS answer record in response"); console.error(err); throw err; } return { answer: resp.body.answer.map(function (ans) { return { data: ans.data, ttl: ans.ttl }; }) }; }); }; ACME._http01 = function (me, auth) { var url = encodeURIComponent(auth.challengeUrl); return new me.request({ url: me._baseUrl + "/api/http?url=" + url }).then(function (resp) { return resp.body; }); }; ACME._removeChallenge = function (me, options, auth) { var challengers = options.challenges || {}; var removeChallenge = (challengers[auth.type] && challengers[auth.type].remove) || options.removeChallenge; if (1 === removeChallenge.length) { removeChallenge(auth).then(function () {}, function () {}); } else if (2 === removeChallenge.length) { removeChallenge(auth, function (err) { return err; }); } else { if (!ACME._removeChallengeWarn) { console.warn("Please update to acme-v2 removeChallenge(options) or removeChallenge(options, cb)."); console.warn("The API has been changed for compatibility with all ACME / Let's Encrypt challenge types."); ACME._removeChallengeWarn = true; } removeChallenge(auth.request.identifier, auth.token, function () {}); } }; Enc.bufToUrlBase64 = function (u8) { return Enc.bufToBase64(u8) .replace(/\+/g, '-').replace(/\//g, '_').replace(/=/g, ''); }; Enc.bufToBase64 = function (u8) { var bin = ''; u8.forEach(function (i) { bin += String.fromCharCode(i); }); return btoa(bin); }; Crypto._sha = function (sha, str) { var encoder = new TextEncoder(); var data = encoder.encode(str); sha = 'SHA-' + sha.replace(/^sha-?/i, ''); return window.crypto.subtle.digest(sha, data).then(function (hash) { return Enc.bufToUrlBase64(new Uint8Array(hash)); }); }; }('undefined' === typeof window ? module.exports : window));