WIP copy over node csr gen
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// 1.2.840.10045.3.1.7
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// prime256v1 (ANSI X9.62 named elliptic curve)
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var OBJ_ID_EC = '06 08 2A8648CE3D030107'.replace(/\s+/g, '').toLowerCase();
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// 1.3.132.0.34
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// secp384r1 (SECG (Certicom) named elliptic curve)
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var OBJ_ID_EC_384 = '06 05 2B81040022'.replace(/\s+/g, '').toLowerCase();
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var ECDSACSR = {};
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var ECDSA = {};
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var DER = {};
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var PEM = {};
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var ASN1;
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var Hex = {};
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var AB = {};
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//
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// CSR - the main event
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//
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ECDSACSR.create = function createEcCsr(keypem, domains) {
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var pemblock = PEM.parseBlock(keypem);
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var ecpub = PEM.parseEcPubkey(pemblock.der);
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var request = ECDSACSR.request(ecpub, domains);
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return AB.fromHex(ECDSACSR.sign(keypem, request));
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};
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ECDSACSR.request = function createCsrBodyEc(xy, domains) {
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var publen = xy.x.byteLength;
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var compression = '04';
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var hxy = '';
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// 04 == x+y, 02 == x-only
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if (xy.y) {
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publen += xy.y.byteLength;
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} else {
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// Note: I don't intend to support compression - it isn't used by most
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// libraries and it requir more dependencies for bigint ops to deflate.
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// This is more just a placeholder. It won't work right now anyway
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// because compression requires an exta bit stored (odd vs even), which
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// I haven't learned yet, and I'm not sure if it's allowed at all
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compression = '02';
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}
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hxy += Hex.fromAB(xy.x);
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if (xy.y) { hxy += Hex.fromAB(xy.y); }
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// Sorry for the mess, but it is what it is
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return ASN1('30'
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// Version (0)
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, ASN1.UInt('00')
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// CN / Subject
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, ASN1('30'
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, ASN1('31'
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, ASN1('30'
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// object id (commonName)
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, ASN1('06', '55 04 03')
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, ASN1('0C', Hex.fromString(domains[0])))))
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// EC P-256 Public Key
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, ASN1('30'
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, ASN1('30'
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// 1.2.840.10045.2.1 ecPublicKey
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// (ANSI X9.62 public key type)
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, ASN1('06', '2A 86 48 CE 3D 02 01')
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// 1.2.840.10045.3.1.7 prime256v1
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// (ANSI X9.62 named elliptic curve)
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, ASN1('06', '2A 86 48 CE 3D 03 01 07')
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)
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, ASN1.BitStr(compression + hxy))
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// CSR Extension Subject Alternative Names
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, ASN1('A0'
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, ASN1('30'
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// (extensionRequest (PKCS #9 via CRMF))
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, ASN1('06', '2A 86 48 86 F7 0D 01 09 0E')
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, ASN1('31'
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, ASN1('30'
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, ASN1('30'
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// (subjectAltName (X.509 extension))
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, ASN1('06', '55 1D 11')
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, ASN1('04'
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, ASN1('30', domains.map(function (d) {
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return ASN1('82', Hex.fromString(d));
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}).join(''))))))))
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);
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};
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ECDSACSR.sign = function csrEcSig(keypem, request) {
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var sig = ECDSA.sign(keypem, AB.fromHex(request));
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var rLen = sig.r.byteLength;
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var rc = '';
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var sLen = sig.s.byteLength;
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var sc = '';
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if (0x80 & new Uint8Array(sig.r)[0]) { rc = '00'; rLen += 1; }
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if (0x80 & new Uint8Array(sig.s)[0]) { sc = '00'; sLen += 1; }
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return ASN1('30'
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// The Full CSR Request Body
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, request
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// The Signature Type
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, ASN1('30'
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// 1.2.840.10045.4.3.2 ecdsaWithSHA256
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// (ANSI X9.62 ECDSA algorithm with SHA256)
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, ASN1('06', '2A 86 48 CE 3D 04 03 02')
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)
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// The Signature, embedded in a Bit Stream
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, ASN1.BitStr(
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// As far as I can tell this is a completely separate ASN.1 structure
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// that just so happens to be embedded in a Bit String of another ASN.1
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ASN1('30'
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, ASN1.UInt(Hex.fromAB(sig.r))
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, ASN1.UInt(Hex.fromAB(sig.s))))
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);
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};
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//
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// ECDSA
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//
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// Took some tips from https://gist.github.com/codermapuche/da4f96cdb6d5ff53b7ebc156ec46a10a
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ECDSA.sign = function signEc(keypem, ab) {
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// Signer is a stream
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var sign = crypto.createSign('SHA256');
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sign.write(new Uint8Array(ab));
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sign.end();
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// The signature is ASN1 encoded
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var sig = sign.sign(keypem);
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// Convert to a JavaScript ArrayBuffer just because
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sig = new Uint8Array(sig.buffer.slice(sig.byteOffset, sig.byteOffset + sig.byteLength));
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// The first two bytes '30 xx' signify SEQUENCE and LENGTH
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// The sequence length byte will be a single byte because the signature is less that 128 bytes (0x80, 1024-bit)
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// (this would not be true for P-521, but I'm not supporting that yet)
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// The 3rd byte will be '02', signifying INTEGER
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// The 4th byte will tell us the length of 'r' (which, on occassion, will be less than the full 255 bytes)
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var rIndex = 3;
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var rLen = sig[rIndex];
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var rEnd = rIndex + 1 + rLen;
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var sIndex = rEnd + 1;
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var sLen = sig[sIndex];
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var sEnd = sIndex + 1 + sLen;
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var r = sig.slice(rIndex + 1, rEnd);
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var s = sig.slice(sIndex + 1, sEnd); // this should be end-of-file
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// ASN1 INTEGER types use the high-order bit to signify a negative number,
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// hence a leading '00' is used for numbers that begin with '80' or greater
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// which is why r length is sometimes a byte longer than its bit length
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if (0 === s[0]) { s = s.slice(1); }
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if (0 === r[0]) { r = r.slice(1); }
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return { raw: sig.buffer, r: r.buffer, s: s.buffer };
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};
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'use strict';
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var crypto = require('crypto');
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var ASN1 = require('./asn1.js');
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var Enc = require('./encoding.js');
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var PEM = require('./pem.js');
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var X509 = require('./x509.js');
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var RSA = {};
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/*global Promise*/
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var CSR = module.exports = function rsacsr(opts) {
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// We're using a Promise here to be compatible with the browser version
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// which will probably use the webcrypto API for some of the conversions
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opts = CSR._prepare(opts);
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return CSR.create(opts).then(function (bytes) {
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return CSR._encode(opts, bytes);
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});
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};
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CSR._prepare = function (opts) {
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var Rasha;
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opts = JSON.parse(JSON.stringify(opts));
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var pem, jwk;
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// We do a bit of extra error checking for user convenience
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if (!opts) { throw new Error("You must pass options with key and domains to rsacsr"); }
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if (!Array.isArray(opts.domains) || 0 === opts.domains.length) {
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new Error("You must pass options.domains as a non-empty array");
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}
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// I need to check that 例.中国 is a valid domain name
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if (!opts.domains.every(function (d) {
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// allow punycode? xn--
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if ('string' === typeof d /*&& /\./.test(d) && !/--/.test(d)*/) {
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return true;
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}
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})) {
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throw new Error("You must pass options.domains as strings");
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}
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if (opts.pem) {
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pem = opts.pem;
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} else if (opts.jwk) {
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jwk = opts.jwk;
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} else {
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if (!opts.key) {
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throw new Error("You must pass options.key as a JSON web key");
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} else if (opts.key.kty) {
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jwk = opts.key;
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} else {
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pem = opts.key;
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}
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}
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if (pem) {
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try {
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Rasha = require('rasha');
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} catch(e) {
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throw new Error("Rasha.js is an optional dependency for PEM-to-JWK.\n"
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+ "Install it if you'd like to use it:\n"
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+ "\tnpm install --save rasha\n"
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+ "Otherwise supply a jwk as the private key."
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);
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}
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jwk = Rasha.importSync({ pem: pem });
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}
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opts.jwk = jwk;
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return opts;
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};
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CSR.sync = function (opts) {
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opts = CSR._prepare(opts);
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var bytes = CSR.createSync(opts);
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return CSR._encode(opts, bytes);
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};
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CSR._encode = function (opts, bytes) {
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if ('der' === (opts.encoding||'').toLowerCase()) {
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return bytes;
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}
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return PEM.packBlock({
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type: "CERTIFICATE REQUEST"
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, bytes: bytes /* { jwk: jwk, domains: opts.domains } */
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});
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};
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CSR.createSync = function createCsr(opts) {
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var hex = CSR.request(opts.jwk, opts.domains);
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var csr = CSR.signSync(opts.jwk, hex);
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return Enc.hexToBuf(csr);
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};
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CSR.create = function createCsr(opts) {
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var hex = CSR.request(opts.jwk, opts.domains);
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return CSR.sign(opts.jwk, hex).then(function (csr) {
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return Enc.hexToBuf(csr);
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});
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};
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CSR.request = function createCsrBodyEc(jwk, domains) {
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var asn1pub = X509.packCsrPublicKey(jwk);
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return X509.packCsr(asn1pub, domains);
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};
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CSR.signSync = function csrEcSig(jwk, request) {
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var keypem = PEM.packBlock({ type: "RSA PRIVATE KEY", bytes: X509.packPkcs1(jwk) });
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var sig = RSA.signSync(keypem, Enc.hexToBuf(request));
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return CSR.toDer({ request: request, signature: sig });
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};
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CSR.sign = function csrEcSig(jwk, request) {
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var keypem = PEM.packBlock({ type: "RSA PRIVATE KEY", bytes: X509.packPkcs1(jwk) });
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return RSA.sign(keypem, Enc.hexToBuf(request)).then(function (sig) {
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return CSR.toDer({ request: request, signature: sig });
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});
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};
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CSR.toDer = function encode(opts) {
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var sty = ASN1('30'
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// 1.2.840.113549.1.1.11 sha256WithRSAEncryption (PKCS #1)
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, ASN1('06', '2a864886f70d01010b')
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, ASN1('05')
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);
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return ASN1('30'
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// The Full CSR Request Body
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, opts.request
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// The Signature Type
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, sty
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// The Signature
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, ASN1.BitStr(Enc.bufToHex(opts.signature))
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);
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};
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//
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// RSA
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//
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// Took some tips from https://gist.github.com/codermapuche/da4f96cdb6d5ff53b7ebc156ec46a10a
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RSA.signSync = function signRsaSync(keypem, ab) {
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// Signer is a stream
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var sign = crypto.createSign('SHA256');
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sign.write(new Uint8Array(ab));
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sign.end();
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// The signature is ASN1 encoded, as it turns out
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var sig = sign.sign(keypem);
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// Convert to a JavaScript ArrayBuffer just because
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return new Uint8Array(sig.buffer.slice(sig.byteOffset, sig.byteOffset + sig.byteLength));
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};
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RSA.sign = function signRsa(keypem, ab) {
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return Promise.resolve().then(function () {
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return RSA.signSync(keypem, ab);
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});
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};
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X509.packCsrRsa = function (asn1pubkey, domains) {
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return ASN1('30'
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// Version (0)
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, ASN1.UInt('00')
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// 2.5.4.3 commonName (X.520 DN component)
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, ASN1('30', ASN1('31', ASN1('30', ASN1('06', '550403'), ASN1('0c', Enc.utf8ToHex(domains[0])))))
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// Public Key (RSA or EC)
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, asn1pubkey
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// Request Body
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, ASN1('a0'
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, ASN1('30'
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// 1.2.840.113549.1.9.14 extensionRequest (PKCS #9 via CRMF)
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, ASN1('06', '2a864886f70d01090e')
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, ASN1('31'
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, ASN1('30'
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, ASN1('30'
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// 2.5.29.17 subjectAltName (X.509 extension)
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, ASN1('06', '551d11')
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, ASN1('04'
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, ASN1('30', domains.map(function (d) {
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return ASN1('82', Enc.utf8ToHex(d));
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}).join(''))))))))
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);
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};
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X509.packPkcs1 = function (jwk) {
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var n = ASN1.UInt(Enc.base64ToHex(jwk.n));
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var e = ASN1.UInt(Enc.base64ToHex(jwk.e));
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if (!jwk.d) {
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return Enc.hexToBuf(ASN1('30', n, e));
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}
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return Enc.hexToBuf(ASN1('30'
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, ASN1.UInt('00')
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, n
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, e
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, ASN1.UInt(Enc.base64ToHex(jwk.d))
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, ASN1.UInt(Enc.base64ToHex(jwk.p))
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, ASN1.UInt(Enc.base64ToHex(jwk.q))
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, ASN1.UInt(Enc.base64ToHex(jwk.dp))
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, ASN1.UInt(Enc.base64ToHex(jwk.dq))
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, ASN1.UInt(Enc.base64ToHex(jwk.qi))
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));
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};
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X509.packCsrRsaPublicKey = function (jwk) {
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// Sequence the key
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var n = ASN1.UInt(Enc.base64ToHex(jwk.n));
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var e = ASN1.UInt(Enc.base64ToHex(jwk.e));
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var asn1pub = ASN1('30', n, e);
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//var asn1pub = X509.packPkcs1({ kty: jwk.kty, n: jwk.n, e: jwk.e });
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// Add the CSR pub key header
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return ASN1('30', ASN1('30', ASN1('06', '2a864886f70d010101'), ASN1('05')), ASN1.BitStr(asn1pub));
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};
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