gecko-dev/dom/crypto/test/test_WebCrypto.html

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<!DOCTYPE html>
<html>
<head>
<title>WebCrypto Test Suite</title>
<meta http-equiv="Content-Type" content="text/html;charset=utf-8" />
<link rel="stylesheet" href="./test_WebCrypto.css"/>
<script src="/tests/SimpleTest/SimpleTest.js"></script>
<!-- Utilities for manipulating ABVs -->
<script src="util.js"></script>
<!-- A simple wrapper around IndexedDB -->
<script src="simpledb.js"></script>
<!-- Test vectors drawn from the literature -->
<script src="./test-vectors.js"></script>
<!-- General testing framework -->
<script src="./test-array.js"></script>
<script>/*<![CDATA[*/
"use strict";
// -----------------------------------------------------------------------------
TestArray.addTest(
"Test for presence of WebCrypto API methods",
function() {
var that = this;
this.complete(
exists(window.crypto.subtle) &&
exists(window.crypto.subtle.encrypt) &&
exists(window.crypto.subtle.decrypt) &&
exists(window.crypto.subtle.sign) &&
exists(window.crypto.subtle.verify) &&
exists(window.crypto.subtle.digest) &&
exists(window.crypto.subtle.importKey) &&
exists(window.crypto.subtle.exportKey) &&
exists(window.crypto.subtle.generateKey) &&
exists(window.crypto.subtle.deriveKey) &&
exists(window.crypto.subtle.deriveBits)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Clean failure on a mal-formed algorithm",
function() {
var that = this;
var alg = {
get name() {
throw "Oh no, no name!";
}
};
crypto.subtle.importKey("raw", tv.raw, alg, true, ["encrypt"])
.then(
error(that),
complete(that, function(x) { return true; })
);
}
)
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import / export round-trip with 'raw'",
function() {
var that = this;
var alg = "AES-GCM";
function doExport(x) {
if (!hasKeyFields(x)) {
window.result = x;
throw "Invalid key; missing field(s)";
} else if ((x.algorithm.name != alg) ||
(x.algorithm.length != 8 * tv.raw.length) ||
(x.type != "secret") ||
(!x.extractable) ||
(x.usages.length != 1) ||
(x.usages[0] != 'encrypt')){
throw "Invalid key: incorrect key data";
}
return crypto.subtle.exportKey("raw", x);
}
crypto.subtle.importKey("raw", tv.raw, alg, true, ["encrypt"])
.then(doExport, error(that))
.then(
memcmp_complete(that, tv.raw),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import failure with format 'raw'",
function() {
var that = this;
var alg = "AES-GCM";
crypto.subtle.importKey("raw", tv.negative_raw, alg, true, ["encrypt"])
.then(error(that), complete(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Proper handling of an ABV representing part of a buffer",
function() {
var that = this;
var alg = "AES-GCM";
var u8 = new Uint8Array([0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f,
0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17,
0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f]);
var u32 = new Uint32Array(u8.buffer, 8, 4);
var out = u8.subarray(8, 24)
function doExport(x) {
return crypto.subtle.exportKey("raw", x);
}
crypto.subtle.importKey("raw", u32, alg, true, ["encrypt"])
.then(doExport, error(that))
.then(memcmp_complete(that, out), error(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import / export round-trip with 'pkcs8'",
function() {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-1" };
function doExport(x) {
if (!hasKeyFields(x)) {
throw "Invalid key; missing field(s)";
} else if ((x.algorithm.name != alg.name) ||
(x.algorithm.hash.name != alg.hash) ||
(x.algorithm.modulusLength != 512) ||
(x.algorithm.publicExponent.byteLength != 3) ||
(x.type != "private") ||
(!x.extractable) ||
(x.usages.length != 1) ||
(x.usages[0] != 'sign')){
throw "Invalid key: incorrect key data";
}
return crypto.subtle.exportKey("pkcs8", x);
}
crypto.subtle.importKey("pkcs8", tv.pkcs8, alg, true, ["sign"])
.then(doExport, error(that))
.then(
memcmp_complete(that, tv.pkcs8),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import failure with format 'pkcs8'",
function() {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-1" };
crypto.subtle.importKey("pkcs8", tv.negative_pkcs8, alg, true, ["encrypt"])
.then(error(that), complete(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import / export round-trip with 'spki'",
function() {
var that = this;
var alg = "RSAES-PKCS1-v1_5";
function doExport(x) {
if (!hasKeyFields(x)) {
throw "Invalid key; missing field(s)";
} else if ((x.algorithm.name != alg) ||
(x.algorithm.modulusLength != 1024) ||
(x.algorithm.publicExponent.byteLength != 3) ||
(x.type != "public") ||
(!x.extractable) ||
(x.usages.length != 1) ||
(x.usages[0] != 'encrypt')){
throw "Invalid key: incorrect key data";
}
return crypto.subtle.exportKey("spki", x);
}
crypto.subtle.importKey("spki", tv.spki, alg, true, ["encrypt"])
.then(doExport, error(that))
.then(
memcmp_complete(that, tv.spki),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import failure with format 'spki'",
function() {
var that = this;
var alg = "RSAES-PKCS1-v1_5";
crypto.subtle.importKey("spki", tv.negative_spki, alg, true, ["encrypt"])
.then(error(that), complete(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Refuse to export non-extractable key",
function() {
var that = this;
var alg = "AES-GCM";
function doExport(x) {
return crypto.subtle.exportKey("raw", x);
}
crypto.subtle.importKey("raw", tv.raw, alg, false, ["encrypt"])
.then(doExport, error(that))
.then(
error(that),
complete(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"IndexedDB store / retrieve round-trip",
function() {
var that = this;
var alg = "AES-GCM";
var importedKey;
var dbname = "keyDB";
var dbstore = "keystore";
var dbversion = 1;
var dbkey = 0;
var db;
function doIndexedDB(x) {
importedKey = x;
var req = indexedDB.deleteDatabase(dbname);
req.onerror = error(that);
req.onsuccess = doCreateDB;
}
function doCreateDB() {
var req = indexedDB.open(dbname, dbversion);
req.onerror = error(that);
req.onupgradeneeded = function(e) {
db = e.target.result;
db.createObjectStore(dbstore, {keyPath: "id"});
}
req.onsuccess = doPut;
}
function doPut() {
var req = db.transaction([dbstore], "readwrite")
.objectStore(dbstore)
.add({id: dbkey, val: importedKey});
req.onerror = error(that);
req.onsuccess = doGet;
}
function doGet() {
var req = db.transaction([dbstore], "readwrite")
.objectStore(dbstore)
.get(dbkey);
req.onerror = error(that);
req.onsuccess = complete(that, function(e) {
return hasKeyFields(e.target.result.val);
});
}
crypto.subtle.importKey("raw", tv.raw, alg, false, ['encrypt'])
.then(doIndexedDB, error(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Generate a 256-bit HMAC-SHA-256 key",
function() {
var that = this;
var alg = { name: "HMAC", length: 256, hash: {name: "SHA-256"} };
crypto.subtle.generateKey(alg, true, ["sign", "verify"]).then(
complete(that, function(x) {
return hasKeyFields(x) && x.algorithm.length == 256;
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Generate a 256-bit HMAC-SHA-256 key without specifying a key length",
function() {
var that = this;
var alg = { name: "HMAC", hash: {name: "SHA-256"} };
crypto.subtle.generateKey(alg, true, ["sign", "verify"]).then(
complete(that, function(x) {
return hasKeyFields(x) && x.algorithm.length == 512;
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Generate a 256-bit HMAC-SHA-512 key without specifying a key length",
function() {
var that = this;
var alg = { name: "HMAC", hash: {name: "SHA-512"} };
crypto.subtle.generateKey(alg, true, ["sign", "verify"]).then(
complete(that, function(x) {
return hasKeyFields(x) && x.algorithm.length == 1024;
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Fail generating an HMAC key when specifying an invalid hash algorithm",
function() {
var that = this;
var alg = { name: "HMAC", hash: {name: "SHA-123"} };
crypto.subtle.generateKey(alg, true, ["sign", "verify"]).then(
error(that),
complete(that, function() { return true; })
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Fail generating an HMAC key when specifying a zero length",
function() {
var that = this;
var alg = { name: "HMAC", hash: {name: "SHA-256"}, length: 0 };
crypto.subtle.generateKey(alg, true, ["sign", "verify"]).then(
error(that),
complete(that, function() { return true; })
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Generate a 192-bit AES key",
function() {
var that = this;
var alg = { name: "AES-GCM", length: 192 };
crypto.subtle.generateKey(alg, true, ["encrypt"]).then(
complete(that, function(x) {
return hasKeyFields(x);
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Generate a 1024-bit RSA key",
function() {
var that = this;
var alg = {
name: "RSAES-PKCS1-v1_5",
modulusLength: 1024,
publicExponent: new Uint8Array([0x01, 0x00, 0x01])
};
crypto.subtle.generateKey(alg, false, ["encrypt", "decrypt"]).then(
complete(that, function(x) {
return exists(x.publicKey) &&
(x.publicKey.algorithm.name == alg.name) &&
(x.publicKey.algorithm.modulusLength == alg.modulusLength) &&
(x.publicKey.type == "public") &&
x.publicKey.extractable &&
(x.publicKey.usages.length == 1) &&
(x.publicKey.usages[0] == "encrypt") &&
exists(x.privateKey) &&
(x.privateKey.algorithm.name == alg.name) &&
(x.privateKey.algorithm.modulusLength == alg.modulusLength) &&
(x.privateKey.type == "private") &&
!x.privateKey.extractable &&
(x.privateKey.usages.length == 1) &&
(x.privateKey.usages[0] == "decrypt");
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Fail cleanly when NSS refuses to generate a key pair",
function() {
var that = this;
var alg = {
name: "RSAES-PKCS1-v1_5",
modulusLength: 2299, // NSS does not like this key length
publicExponent: new Uint8Array([0x01, 0x00, 0x01])
};
crypto.subtle.generateKey(alg, false, ["encrypt"])
.then( error(that), complete(that) );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"SHA-256 digest",
function() {
var that = this;
crypto.subtle.digest("SHA-256", tv.sha256.data).then(
memcmp_complete(that, tv.sha256.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Fail cleanly on unknown hash algorithm",
function() {
var that = this;
crypto.subtle.digest("GOST-34_311-95", tv.sha256.data).then(
error(that),
complete(that, function() { return true; })
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-CBC encrypt",
function () {
var that = this;
function doEncrypt(x) {
console.log(x);
return crypto.subtle.encrypt(
{ name: "AES-CBC", iv: tv.aes_cbc_enc.iv },
x, tv.aes_cbc_enc.data);
}
crypto.subtle.importKey("raw", tv.aes_cbc_enc.key, "AES-CBC", false, ['encrypt'])
.then(doEncrypt)
.then(
memcmp_complete(that, tv.aes_cbc_enc.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-CBC encrypt with wrong IV size",
function () {
var that = this;
function encrypt(x, iv) {
console.log(x);
return crypto.subtle.encrypt(
{ name: "AES-CBC", iv: iv },
x, tv.aes_cbc_enc.data);
}
function doEncrypt(x) {
return encrypt(x, new Uint8Array(15))
.then(
null,
function () { return encrypt(new Uint8Array(17)); }
);
}
crypto.subtle.importKey("raw", tv.aes_cbc_enc.key, "AES-CBC", false, ['encrypt'])
.then(doEncrypt)
.then(
error(that),
complete(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-CBC decrypt",
function () {
var that = this;
function doDecrypt(x) {
return crypto.subtle.decrypt(
{ name: "AES-CBC", iv: tv.aes_cbc_dec.iv },
x, tv.aes_cbc_dec.data);
}
crypto.subtle.importKey("raw", tv.aes_cbc_dec.key, "AES-CBC", false, ['decrypt'])
.then(doDecrypt)
.then(
memcmp_complete(that, tv.aes_cbc_dec.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-CBC decrypt with wrong IV size",
function () {
var that = this;
function decrypt(x, iv) {
return crypto.subtle.decrypt(
{ name: "AES-CBC", iv: iv },
x, tv.aes_cbc_dec.data);
}
function doDecrypt(x) {
return decrypt(x, new Uint8Array(15))
.then(
null,
function () { return decrypt(x, new Uint8Array(17)); }
);
}
crypto.subtle.importKey("raw", tv.aes_cbc_dec.key, "AES-CBC", false, ['decrypt'])
.then(doDecrypt)
.then(
error(that),
complete(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-CTR encryption",
function () {
var that = this;
function doEncrypt(x) {
return crypto.subtle.encrypt(
{ name: "AES-CTR", counter: tv.aes_ctr_enc.iv, length: 32 },
x, tv.aes_ctr_enc.data);
}
crypto.subtle.importKey("raw", tv.aes_ctr_enc.key, "AES-CTR", false, ['encrypt'])
.then(doEncrypt)
.then(
memcmp_complete(that, tv.aes_ctr_enc.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-CTR encryption with wrong IV size",
function () {
var that = this;
function encrypt(x, iv) {
return crypto.subtle.encrypt(
{ name: "AES-CTR", counter: iv, length: 32 },
x, tv.aes_ctr_enc.data);
}
function doEncrypt(x) {
return encrypt(x, new Uint8Array(15))
.then(
null,
function () { return encrypt(x, new Uint8Array(17)); }
);
}
crypto.subtle.importKey("raw", tv.aes_ctr_enc.key, "AES-CTR", false, ['encrypt'])
.then(doEncrypt)
.then(
error(that),
complete(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-CTR decryption",
function () {
var that = this;
function doDecrypt(x) {
return crypto.subtle.decrypt(
{ name: "AES-CTR", counter: tv.aes_ctr_dec.iv, length: 32 },
x, tv.aes_ctr_dec.data);
}
crypto.subtle.importKey("raw", tv.aes_ctr_dec.key, "AES-CTR", false, ['decrypt'])
.then(doDecrypt)
.then(
memcmp_complete(that, tv.aes_ctr_dec.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-CTR decryption with wrong IV size",
function () {
var that = this;
function doDecrypt(x, iv) {
return crypto.subtle.decrypt(
{ name: "AES-CTR", counter: iv, length: 32 },
x, tv.aes_ctr_dec.data);
}
function decrypt(x) {
return decrypt(x, new Uint8Array(15))
.then(
null,
function () { return decrypt(x, new Uint8Array(17)); }
);
}
crypto.subtle.importKey("raw", tv.aes_ctr_dec.key, "AES-CTR", false, ['decrypt'])
.then(doDecrypt)
.then(
error(that),
complete(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-GCM encryption",
function () {
var that = this;
function doEncrypt(x) {
return crypto.subtle.encrypt(
{
name: "AES-GCM",
iv: tv.aes_gcm_enc.iv,
additionalData: tv.aes_gcm_enc.adata,
tagLength: 128
},
x, tv.aes_gcm_enc.data);
}
crypto.subtle.importKey("raw", tv.aes_gcm_enc.key, "AES-GCM", false, ['encrypt'])
.then(doEncrypt)
.then(
memcmp_complete(that, tv.aes_gcm_enc.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-GCM decryption",
function () {
var that = this;
function doDecrypt(x) {
return crypto.subtle.decrypt(
{
name: "AES-GCM",
iv: tv.aes_gcm_dec.iv,
additionalData: tv.aes_gcm_dec.adata,
tagLength: 128
},
x, tv.aes_gcm_dec.data);
}
crypto.subtle.importKey("raw", tv.aes_gcm_dec.key, "AES-GCM", false, ['decrypt'])
.then(doDecrypt)
.then(
memcmp_complete(that, tv.aes_gcm_dec.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-GCM decryption, failing authentication check",
function () {
var that = this;
function doDecrypt(x) {
return crypto.subtle.decrypt(
{
name: "AES-GCM",
iv: tv.aes_gcm_dec_fail.iv,
additionalData: tv.aes_gcm_dec_fail.adata,
tagLength: 128
},
x, tv.aes_gcm_dec_fail.data);
}
crypto.subtle.importKey("raw", tv.aes_gcm_dec_fail.key, "AES-GCM", false, ['decrypt'])
.then(doDecrypt)
.then(
error(that),
complete(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"HMAC SHA-256 sign",
function() {
var that = this;
var alg = {
name: "HMAC",
hash: "SHA-256"
}
function doSign(x) {
return crypto.subtle.sign("HMAC", x, tv.hmac_sign.data);
}
crypto.subtle.importKey("raw", tv.hmac_sign.key, alg, false, ['sign'])
.then(doSign)
.then(
memcmp_complete(that, tv.hmac_sign.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"HMAC SHA-256 verify",
function() {
var that = this;
var alg = {
name: "HMAC",
hash: "SHA-256"
}
function doVerify(x) {
return crypto.subtle.verify("HMAC", x, tv.hmac_verify.sig, tv.hmac_verify.data);
}
crypto.subtle.importKey("raw", tv.hmac_verify.key, alg, false, ['verify'])
.then(doVerify)
.then(
complete(that, function(x) { return !!x; }),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"HMAC SHA-256, failing verification due to bad signature",
function() {
var that = this;
var alg = {
name: "HMAC",
hash: "SHA-256"
}
function doVerify(x) {
return crypto.subtle.verify("HMAC", x, tv.hmac_verify.sig_fail,
tv.hmac_verify.data);
}
crypto.subtle.importKey("raw", tv.hmac_verify.key, alg, false, ['verify'])
.then(doVerify)
.then(
complete(that, function(x) { return !x; }),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"HMAC SHA-256, failing verification due to key usage restriction",
function() {
var that = this;
var alg = {
name: "HMAC",
hash: "SHA-256"
}
function doVerify(x) {
return crypto.subtle.verify("HMAC", x, tv.hmac_verify.sig,
tv.hmac_verify.data);
}
crypto.subtle.importKey("raw", tv.hmac_verify.key, alg, false, ['encrypt'])
.then(doVerify)
.then(
error(that),
complete(that, function(x) { return true; })
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSAES-PKCS#1 encrypt/decrypt round-trip",
function () {
var that = this;
var privKey, pubKey;
var alg = {name:"RSAES-PKCS1-v1_5"};
var privKey, pubKey, data, ct, pt;
function setPriv(x) { privKey = x; }
function setPub(x) { pubKey = x; }
function doEncrypt() {
return crypto.subtle.encrypt(alg.name, pubKey, tv.rsaes.data);
}
function doDecrypt(x) {
return crypto.subtle.decrypt(alg.name, privKey, x);
}
function fail() { error(that); }
Promise.all([
crypto.subtle.importKey("pkcs8", tv.rsaes.pkcs8, alg, false, ['decrypt'])
.then(setPriv, error(that)),
crypto.subtle.importKey("spki", tv.rsaes.spki, alg, false, ['encrypt'])
.then(setPub, error(that))
]).then(doEncrypt, error(that))
.then(doDecrypt, error(that))
.then(
memcmp_complete(that, tv.rsaes.data),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSAES-PKCS#1 decryption known answer",
function () {
var that = this;
var alg = {name:"RSAES-PKCS1-v1_5"};
function doDecrypt(x) {
return crypto.subtle.decrypt(alg.name, x, tv.rsaes.result);
}
function fail() { error(that); }
crypto.subtle.importKey("pkcs8", tv.rsaes.pkcs8, alg, false, ['decrypt'])
.then( doDecrypt, fail )
.then( memcmp_complete(that, tv.rsaes.data), fail );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSASSA/SHA-1 signature",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-1" };
function doSign(x) {
console.log("sign");
console.log(x);
return crypto.subtle.sign(alg.name, x, tv.rsassa.data);
}
function fail() { console.log("fail"); error(that); }
crypto.subtle.importKey("pkcs8", tv.rsassa.pkcs8, alg, false, ['sign'])
.then( doSign, fail )
.then( memcmp_complete(that, tv.rsassa.sig1), fail );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSASSA verification (SHA-1)",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-1" };
function doVerify(x) {
return crypto.subtle.verify(alg.name, x, tv.rsassa.sig1, tv.rsassa.data);
}
function fail(x) { error(that); }
crypto.subtle.importKey("spki", tv.rsassa.spki, alg, false, ['verify'])
.then( doVerify, fail )
.then(
complete(that, function(x) { return x; }),
fail
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSASSA verification (SHA-1), failing verification",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-1" };
function doVerify(x) {
return crypto.subtle.verify(alg.name, x, tv.rsassa.sig_fail, tv.rsassa.data);
}
function fail(x) { error(that); }
crypto.subtle.importKey("spki", tv.rsassa.spki, alg, false, ['verify'])
.then( doVerify, fail )
.then(
complete(that, function(x) { return !x; }),
fail
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSASSA/SHA-256 signature",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-256" };
function doSign(x) {
return crypto.subtle.sign(alg.name, x, tv.rsassa.data);
}
function fail(x) { console.log(x); error(that); }
crypto.subtle.importKey("pkcs8", tv.rsassa.pkcs8, alg, false, ['sign'])
.then( doSign, fail )
.then( memcmp_complete(that, tv.rsassa.sig256), fail );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSASSA verification (SHA-256)",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-256" };
function doVerify(x) {
return crypto.subtle.verify(alg.name, x, tv.rsassa.sig256, tv.rsassa.data);
}
function fail(x) { error(that); }
crypto.subtle.importKey("spki", tv.rsassa.spki, alg, false, ['verify'])
.then( doVerify, fail )
.then(
complete(that, function(x) { return x; }),
fail
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSASSA verification (SHA-256), failing verification",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-256" };
var use = ['sign', 'verify'];
function doVerify(x) {
console.log("verifying")
return crypto.subtle.verify(alg.name, x, tv.rsassa.sig_fail, tv.rsassa.data);
}
function fail(x) { console.log("failing"); error(that)(x); }
console.log("running")
crypto.subtle.importKey("spki", tv.rsassa.spki, alg, false, ['verify'])
.then( doVerify, fail )
.then(
complete(that, function(x) { return !x; }),
fail
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import raw PBKDF2 key",
function() {
var that = this;
var alg = "PBKDF2";
var key = new TextEncoder("utf-8").encode("password");
crypto.subtle.importKey("raw", key, alg, false, ["deriveKey"]).then(
complete(that, hasKeyFields),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import raw PBKDF2 key and derive bits using HMAC-SHA-1",
function() {
var that = this;
var alg = "PBKDF2";
var key = tv.pbkdf2_sha1.password;
function doDerive(x) {
console.log("deriving");
if (!hasKeyFields(x)) {
throw "Invalid key; missing field(s)";
}
var alg = {
name: "PBKDF2",
hash: "SHA-1",
salt: tv.pbkdf2_sha1.salt,
iterations: tv.pbkdf2_sha1.iterations
};
return crypto.subtle.deriveBits(alg, x, tv.pbkdf2_sha1.length);
}
function fail(x) { console.log("failing"); error(that)(x); }
crypto.subtle.importKey("raw", key, alg, false, ["deriveKey"])
.then( doDerive, fail )
.then( memcmp_complete(that, tv.pbkdf2_sha1.derived), fail );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import raw PBKDF2 key and derive a new key using HMAC-SHA-1",
function() {
var that = this;
var alg = "PBKDF2";
var key = tv.pbkdf2_sha1.password;
function doDerive(x) {
console.log("deriving");
if (!hasKeyFields(x)) {
throw "Invalid key; missing field(s)";
}
var alg = {
name: "PBKDF2",
hash: "SHA-1",
salt: tv.pbkdf2_sha1.salt,
iterations: tv.pbkdf2_sha1.iterations
};
var algDerived = {
name: "HMAC",
hash: {name: "SHA-1"}
};
return crypto.subtle.deriveKey(alg, x, algDerived, false, ["sign", "verify"])
.then(function (x) {
if (!hasKeyFields(x)) {
throw "Invalid key; missing field(s)";
}
if (x.algorithm.length != 512) {
throw "Invalid key; incorrect length";
}
return x;
});
}
function doSignAndVerify(x) {
var data = new Uint8Array(1024);
return crypto.subtle.sign("HMAC", x, data)
.then(function (sig) {
return crypto.subtle.verify("HMAC", x, sig, data);
});
}
function fail(x) { console.log("failing"); error(that)(x); }
crypto.subtle.importKey("raw", key, alg, false, ["deriveKey"])
.then( doDerive, fail )
.then( doSignAndVerify, fail )
.then( complete(that), fail );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Import raw PBKDF2 key and derive a new key using HMAC-SHA-1 with custom length",
function() {
var that = this;
function doDerive(x) {
var alg = {
name: "PBKDF2",
hash: "SHA-1",
salt: tv.pbkdf2_sha1.salt,
iterations: tv.pbkdf2_sha1.iterations
};
var algDerived = {name: "HMAC", hash: "SHA-1", length: 128};
return crypto.subtle.deriveKey(alg, x, algDerived, false, ["sign"]);
}
var password = crypto.getRandomValues(new Uint8Array(8));
crypto.subtle.importKey("raw", password, "PBKDF2", false, ["deriveKey"])
.then(doDerive)
.then(complete(that, function (x) {
return hasKeyFields(x) && x.algorithm.length == 128;
}), error(that));
}
);
// -----------------------------------------------------------------------------
/*TestArray.addTest(
"Import raw PBKDF2 key and derive bits using HMAC-SHA-256",
function() {
var that = this;
var alg = "PBKDF2";
var key = tv.pbkdf2_sha256.password;
function doDerive(x) {
console.log("deriving");
if (!hasKeyFields(x)) {
throw "Invalid key; missing field(s)";
}
var alg = {
name: "PBKDF2",
hash: "SHA-256",
salt: tv.pbkdf2_sha256.salt,
iterations: tv.pbkdf2_sha256.iterations
};
return crypto.subtle.deriveBits(alg, x, tv.pbkdf2_sha256.length);
}
function fail(x) { console.log("failing"); error(that)(x); }
crypto.subtle.importKey("raw", key, alg, false, ["deriveKey"])
.then( doDerive, fail )
.then( memcmp_complete(that, tv.pbkdf2_sha256.derived), fail );
}
);*/
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSA-OAEP encrypt/decrypt round-trip",
function () {
var that = this;
var privKey, pubKey;
var alg = {name: "RSA-OAEP", hash: "SHA-1"};
var privKey, pubKey;
function setPriv(x) { privKey = x; }
function setPub(x) { pubKey = x; }
function doEncrypt() {
return crypto.subtle.encrypt(alg, pubKey, tv.rsaoaep.data);
}
function doDecrypt(x) {
return crypto.subtle.decrypt(alg, privKey, x);
}
Promise.all([
crypto.subtle.importKey("pkcs8", tv.rsaoaep.pkcs8, alg, false, ['decrypt'])
.then(setPriv, error(that)),
crypto.subtle.importKey("spki", tv.rsaoaep.spki, alg, false, ['encrypt'])
.then(setPub, error(that))
]).then(doEncrypt, error(that))
.then(doDecrypt, error(that))
.then(
memcmp_complete(that, tv.rsaoaep.data),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSA-OAEP key generation and encrypt/decrypt round-trip (SHA-256)",
function () {
var that = this;
var alg = {
name: "RSA-OAEP",
hash: "SHA-256",
modulusLength: 2048,
publicExponent: new Uint8Array([0x01, 0x00, 0x01])
};
var privKey, pubKey, data = crypto.getRandomValues(new Uint8Array(128));
function setKey(x) { pubKey = x.publicKey; privKey = x.privateKey; }
function doEncrypt() {
return crypto.subtle.encrypt(alg, pubKey, data);
}
function doDecrypt(x) {
return crypto.subtle.decrypt(alg, privKey, x);
}
crypto.subtle.generateKey(alg, false, ['encrypt', 'decrypt'])
.then(setKey, error(that))
.then(doEncrypt, error(that))
.then(doDecrypt, error(that))
.then(
memcmp_complete(that, data),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSA-OAEP decryption known answer",
function () {
var that = this;
var alg = {name: "RSA-OAEP", hash: "SHA-1"};
function doDecrypt(x) {
return crypto.subtle.decrypt(alg, x, tv.rsaoaep.result);
}
function fail() { error(that); }
crypto.subtle.importKey("pkcs8", tv.rsaoaep.pkcs8, alg, false, ['decrypt'])
.then( doDecrypt, fail )
.then( memcmp_complete(that, tv.rsaoaep.data), fail );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSA-OAEP input data length checks (2048-bit key)",
function () {
var that = this;
var privKey, pubKey;
var alg = {
name: "RSA-OAEP",
hash: "SHA-1",
modulusLength: 2048,
publicExponent: new Uint8Array([0x01, 0x00, 0x01])
};
var privKey, pubKey;
function setKey(x) { pubKey = x.publicKey; privKey = x.privateKey; }
function doEncrypt(n) {
return function () {
return crypto.subtle.encrypt(alg, pubKey, new Uint8Array(n));
}
}
crypto.subtle.generateKey(alg, false, ['encrypt'])
.then(setKey, error(that))
.then(doEncrypt(214), error(that))
.then(doEncrypt(215), error(that))
.then(error(that), complete(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"RSA-OAEP key import with invalid hash",
function () {
var that = this;
var alg = {name: "RSA-OAEP", hash: "SHA-123"};
crypto.subtle.importKey("pkcs8", tv.rsaoaep.pkcs8, alg, false, ['decrypt'])
.then(error(that), complete(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Test that RSA-OAEP encrypt/decrypt accepts strings as AlgorithmIdentifiers",
function () {
var that = this;
var alg = {
name: "RSA-OAEP",
hash: "SHA-256",
modulusLength: 2048,
publicExponent: new Uint8Array([0x01, 0x00, 0x01])
};
var privKey, pubKey, data = crypto.getRandomValues(new Uint8Array(128));
function setKey(x) { pubKey = x.publicKey; privKey = x.privateKey; }
function doEncrypt() {
return crypto.subtle.encrypt("RSA-OAEP", pubKey, data);
}
function doDecrypt(x) {
return crypto.subtle.decrypt("RSA-OAEP", privKey, x);
}
crypto.subtle.generateKey(alg, false, ["encrypt", "decrypt"])
.then(setKey)
.then(doEncrypt)
.then(doDecrypt)
.then(memcmp_complete(that, data), error(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Key wrap known answer, using AES-GCM",
function () {
var that = this;
var alg = {
name: "AES-GCM",
iv: tv.key_wrap_known_answer.wrapping_iv,
tagLength: 128
};
var key, wrappingKey;
function doImport(k) {
wrappingKey = k;
return crypto.subtle.importKey("raw", tv.key_wrap_known_answer.key,
alg, true, ['encrypt', 'decrypt']);
}
function doWrap(k) {
key = k;
return crypto.subtle.wrapKey("raw", key, wrappingKey, alg);
}
crypto.subtle.importKey("raw", tv.key_wrap_known_answer.wrapping_key,
alg, false, ['wrapKey'])
.then(doImport, error(that))
.then(doWrap, error(that))
.then(
memcmp_complete(that, tv.key_wrap_known_answer.wrapped_key),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Key wrap failing on non-extractable key",
function () {
var that = this;
var alg = {
name: "AES-GCM",
iv: tv.key_wrap_known_answer.wrapping_iv,
tagLength: 128
};
var key, wrappingKey;
function doImport(k) {
wrappingKey = k;
return crypto.subtle.importKey("raw", tv.key_wrap_known_answer.key,
alg, false, ['encrypt', 'decrypt']);
}
function doWrap(k) {
key = k;
return crypto.subtle.wrapKey("raw", key, wrappingKey, alg);
}
crypto.subtle.importKey("raw", tv.key_wrap_known_answer.wrapping_key,
alg, false, ['wrapKey'])
.then(doImport, error(that))
.then(doWrap, error(that))
.then(
error(that),
complete(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Key unwrap known answer, using AES-GCM",
function () {
var that = this;
var alg = {
name: "AES-GCM",
iv: tv.key_wrap_known_answer.wrapping_iv,
tagLength: 128
};
var key, wrappingKey;
function doUnwrap(k) {
wrappingKey = k;
return crypto.subtle.unwrapKey(
"raw", tv.key_wrap_known_answer.wrapped_key,
wrappingKey, alg,
"AES-GCM", true, ['encrypt', 'decrypt']
);
}
function doExport(k) {
return crypto.subtle.exportKey("raw", k);
}
crypto.subtle.importKey("raw", tv.key_wrap_known_answer.wrapping_key,
alg, false, ['unwrapKey'])
.then(doUnwrap, error(that))
.then(doExport, error(that))
.then(
memcmp_complete(that, tv.key_wrap_known_answer.key),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Key wrap/unwrap round-trip, using RSA-OAEP",
function () {
var that = this;
var oaep = {
name: "RSA-OAEP",
hash: "SHA-256"
};
var gcm = {
name: "AES-GCM",
iv: tv.aes_gcm_enc.iv,
additionalData: tv.aes_gcm_enc.adata,
tagLength: 128
};
var unwrapKey;
function doWrap(keys) {
var originalKey = keys[0];
var wrapKey = keys[1];
unwrapKey = keys[2];
return crypto.subtle.wrapKey("raw", originalKey, wrapKey, oaep);
}
function doUnwrap(wrappedKey) {
return crypto.subtle.unwrapKey("raw", wrappedKey, unwrapKey, oaep,
gcm, false, ['encrypt']);
}
function doEncrypt(aesKey) {
return crypto.subtle.encrypt(gcm, aesKey, tv.aes_gcm_enc.data);
}
// 1.Import:
// -> HMAC key
// -> OAEP wrap key (public)
// -> OAEP unwrap key (private)
// 2. Wrap the HMAC key
// 3. Unwrap it
// 4. Compute HMAC
// 5. Check HMAC value
Promise.all([
crypto.subtle.importKey("raw", tv.aes_gcm_enc.key, gcm, true, ['encrypt']),
crypto.subtle.importKey("spki", tv.rsaoaep.spki, oaep, true, ['wrapKey']),
crypto.subtle.importKey("pkcs8", tv.rsaoaep.pkcs8, oaep, false, ['unwrapKey'])
])
.then(doWrap, error(that))
.then(doUnwrap, error(that))
.then(doEncrypt, error(that))
.then(
memcmp_complete(that, tv.aes_gcm_enc.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK import and use of an AES-GCM key",
function () {
var that = this;
function doEncrypt(x) {
return crypto.subtle.encrypt(
{
name: "AES-GCM",
iv: tv.aes_gcm_enc.iv,
additionalData: tv.aes_gcm_enc.adata,
tagLength: 128
},
x, tv.aes_gcm_enc.data);
}
crypto.subtle.importKey("jwk", tv.aes_gcm_enc.key_jwk, "AES-GCM", false, ['encrypt'])
.then(doEncrypt)
.then(
memcmp_complete(that, tv.aes_gcm_enc.result),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK import and use of an RSASSA-PKCS1-v1_5 private key",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-256" };
function doSign(x) {
return crypto.subtle.sign(alg.name, x, tv.rsassa.data);
}
function fail(x) { console.log(x); error(that); }
crypto.subtle.importKey("jwk", tv.rsassa.jwk_priv, alg, false, ['sign'])
.then( doSign, fail )
.then( memcmp_complete(that, tv.rsassa.sig256), fail );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK import and use of an RSASSA-PKCS1-v1_5 public key",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-256" };
function doVerify(x) {
return crypto.subtle.verify(alg.name, x, tv.rsassa.sig256, tv.rsassa.data);
}
function fail(x) { error(that); }
crypto.subtle.importKey("jwk", tv.rsassa.jwk_pub, alg, false, ['verify'])
.then( doVerify, fail )
.then(
complete(that, function(x) { return x; }),
fail
);
});
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK import failure on incomplete RSA private key (missing 'qi')",
function () {
var that = this;
var alg = { name: "RSA-OAEP", hash: "SHA-256" };
var jwk = {
kty: "RSA",
n: tv.rsassa.jwk_priv.n,
e: tv.rsassa.jwk_priv.e,
d: tv.rsassa.jwk_priv.d,
p: tv.rsassa.jwk_priv.p,
q: tv.rsassa.jwk_priv.q,
dp: tv.rsassa.jwk_priv.dp,
dq: tv.rsassa.jwk_priv.dq,
};
crypto.subtle.importKey("jwk", jwk, alg, true, ['encrypt', 'decrypt'])
.then( error(that), complete(that) );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK import failure on algorithm mismatch",
function () {
var that = this;
var alg = "AES-GCM";
var jwk = { k: "c2l4dGVlbiBieXRlIGtleQ", alg: "A256GCM" };
crypto.subtle.importKey("jwk", jwk, alg, true, ['encrypt', 'decrypt'])
.then( error(that), complete(that) );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK import failure on usages mismatch",
function () {
var that = this;
var alg = "AES-GCM";
var jwk = { k: "c2l4dGVlbiBieXRlIGtleQ", key_ops: ['encrypt'] };
crypto.subtle.importKey("jwk", jwk, alg, true, ['encrypt', 'decrypt'])
.then( error(that), complete(that) );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK import failure on extractable mismatch",
function () {
var that = this;
var alg = "AES-GCM";
var jwk = { k: "c2l4dGVlbiBieXRlIGtleQ", ext: false };
crypto.subtle.importKey("jwk", jwk, alg, true, ['encrypt'])
.then( error(that), complete(that) );
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK export of a symmetric key",
function () {
var that = this;
var alg = "AES-GCM";
var jwk = { k: "c2l4dGVlbiBieXRlIGtleQ" };
function doExport(k) {
return crypto.subtle.exportKey("jwk", k);
}
crypto.subtle.importKey("jwk", jwk, alg, true, ['encrypt', 'decrypt'])
.then(doExport)
.then(
complete(that, function(x) {
return hasBaseJwkFields(x) &&
hasFields(x, ['k']) &&
x.kty == 'oct' &&
x.alg == 'A128GCM' &&
x.ext &&
shallowArrayEquals(x.key_ops, ['encrypt','decrypt']) &&
x.k == jwk.k
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK export of an RSA private key",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-256" };
var jwk = tv.rsassa.jwk_priv;
function doExport(k) {
return crypto.subtle.exportKey("jwk", k);
}
crypto.subtle.importKey("jwk", jwk, alg, true, ['sign'])
.then(doExport)
.then(
complete(that, function(x) {
window.jwk_priv = x;
console.log(JSON.stringify(x));
return hasBaseJwkFields(x) &&
hasFields(x, ['n', 'e', 'd', 'p', 'q', 'dp', 'dq', 'qi']) &&
x.kty == 'RSA' &&
x.alg == 'RS256' &&
x.ext &&
shallowArrayEquals(x.key_ops, ['sign']) &&
x.n == jwk.n &&
x.e == jwk.e &&
x.d == jwk.d &&
x.p == jwk.p &&
x.q == jwk.q &&
x.dp == jwk.dp &&
x.dq == jwk.dq &&
x.qi == jwk.qi;
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK export of an RSA public key",
function () {
var that = this;
var alg = { name: "RSASSA-PKCS1-v1_5", hash: "SHA-256" };
var jwk = tv.rsassa.jwk_pub;
function doExport(k) {
return crypto.subtle.exportKey("jwk", k);
}
crypto.subtle.importKey("jwk", jwk, alg, true, ['verify'])
.then(doExport)
.then(
complete(that, function(x) {
window.jwk_pub = x;
return hasBaseJwkFields(x) &&
hasFields(x, ['n', 'e']) &&
x.kty == 'RSA' &&
x.alg == 'RS256' &&
x.ext &&
shallowArrayEquals(x.key_ops, ['verify']) &&
x.n == jwk.n &&
x.e == jwk.e;
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"JWK wrap/unwrap round-trip, with AES-GCM",
function () {
var that = this;
var genAlg = { name: "HMAC", hash: "SHA-384", length: 512 };
var wrapAlg = { name: "AES-GCM", iv: tv.aes_gcm_enc.iv };
var wrapKey, originalKey, originalKeyJwk;
function doExport(k) {
return crypto.subtle.exportKey("jwk", k);
}
function doWrap() {
return crypto.subtle.wrapKey("jwk", originalKey, wrapKey, wrapAlg);
}
function doUnwrap(wrappedKey) {
return crypto.subtle.unwrapKey("jwk", wrappedKey, wrapKey, wrapAlg,
{ name: "HMAC", hash: "SHA-384"},
true, ['sign', 'verify']);
}
function temperr(x) { return function(y) { console.log("error in "+x); console.log(y); } }
Promise.all([
crypto.subtle.importKey("jwk", tv.aes_gcm_enc.key_jwk,
"AES-GCM", false, ['wrapKey','unwrapKey'])
.then(function(x) { console.log("wrapKey"); wrapKey = x; }),
crypto.subtle.generateKey(genAlg, true, ['sign', 'verify'])
.then(function(x) { console.log("originalKey"); originalKey = x; return x; })
.then(doExport)
.then(function(x) { originalKeyJwk = x; })
])
.then(doWrap, temperr("initial phase"))
.then(doUnwrap, temperr("wrap"))
.then(doExport, temperr("unwrap"))
.then(
complete(that, function(x) {
return exists(x.k) && x.k == originalKeyJwk.k;
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-KW known answer",
function () {
var that = this;
function doWrap(keys) {
var wrapKey = keys[0];
var originalKey = keys[1];
return crypto.subtle.wrapKey("raw", originalKey, wrapKey, "AES-KW");
}
Promise.all([
crypto.subtle.importKey("jwk", tv.aes_kw.wrapping_key,
"AES-KW", false, ['wrapKey']),
crypto.subtle.importKey("jwk", tv.aes_kw.key,
"AES-GCM", true, ['encrypt'])
])
.then(doWrap)
.then(
memcmp_complete(that, tv.aes_kw.wrapped_key),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-KW unwrap failure on tampered key data",
function () {
var that = this;
var tamperedWrappedKey = new Uint8Array(tv.aes_kw.wrapped_key);
tamperedWrappedKey[5] ^= 0xFF;
function doUnwrap(wrapKey) {
return crypto.subtle.unwrapKey("raw", tamperedWrappedKey, wrapKey,
"AES-KW", "AES-GCM",
true, ['encrypt', 'decrypt']);
}
crypto.subtle.importKey("jwk", tv.aes_kw.wrapping_key,
"AES-KW", false, ['unwrapKey'])
.then(doUnwrap)
.then(error(that), complete(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"AES-KW wrap/unwrap round-trip",
function () {
var that = this;
var genAlg = { name: "HMAC", hash: "SHA-384", length: 512 };
var wrapKey, originalKey, originalKeyJwk;
function doExport(k) {
return crypto.subtle.exportKey("jwk", k);
}
function doWrap() {
return crypto.subtle.wrapKey("raw", originalKey, wrapKey, "AES-KW");
}
function doUnwrap(wrappedKey) {
return crypto.subtle.unwrapKey("raw", wrappedKey, wrapKey,
"AES-KW", { name: "HMAC", hash: "SHA-384"},
true, ['sign', 'verify']);
}
Promise.all([
crypto.subtle.importKey("jwk", tv.aes_kw.wrapping_key,
"AES-KW", false, ['wrapKey','unwrapKey'])
.then(function(x) { console.log("wrapKey"); wrapKey = x; }),
crypto.subtle.generateKey(genAlg, true, ['sign'])
.then(function(x) { console.log("originalKey"); originalKey = x; return x; })
.then(doExport)
.then(function(x) { originalKeyJwk = x; })
])
.then(doWrap)
.then(doUnwrap)
.then(doExport)
.then(
complete(that, function(x) {
return exists(x.k) && x.k == originalKeyJwk.k;
}),
error(that)
);
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Test that we return ArrayBuffers not ArrayBufferViews",
function() {
var that = this;
crypto.subtle.digest("SHA-256", tv.sha256.data)
.then(complete(that, function (x) {
return x instanceof ArrayBuffer;
}), error(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Ensure that importing an invalid key doesn't crash",
function () {
var that = this;
// TODO Change the algorithm to "DH" once we support it.
var alg = {name: "RSA-OAEP", hash: "SHA-1"};
crypto.subtle.importKey("pkcs8", tv.broken_pkcs8.dh, alg, false, ["decrypt"])
.then(error(that), complete(that));
}
);
// -----------------------------------------------------------------------------
TestArray.addTest(
"Test that we properly normalize algorithm names",
function() {
var that = this;
var alg = { name: "hmac", hash: {name: "sHa-256"} };
function doGenerateAesKey() {
var alg = { name: "AES-gcm", length: 192 };
return crypto.subtle.generateKey(alg, false, ["encrypt"]);
}
function doGenerateRsaOaepKey() {
var alg = {
name: "rsa-OAEP",
hash: "sha-1",
modulusLength: 2048,
publicExponent: new Uint8Array([0x01, 0x00, 0x01])
};
return crypto.subtle.generateKey(alg, false, ["encrypt"]);
}
function doGenerateRsaSsaPkcs1Key() {
var alg = { name: "RSASSA-pkcs1-V1_5", hash: "SHA-1" };
return crypto.subtle.importKey("pkcs8", tv.pkcs8, alg, true, ["sign"]);
}
crypto.subtle.generateKey(alg, false, ["sign"])
.then(doGenerateAesKey)
.then(doGenerateRsaOaepKey)
.then(doGenerateRsaSsaPkcs1Key)
.then(complete(that), error(that));
}
);
/*]]>*/</script>
</head>
<body>
<div id="content">
<div id="head">
<b>Web</b>Crypto<br>
</div>
<div id="start" onclick="start();">RUN ALL</div>
<div id="resultDiv" class="content">
Summary:
<span class="pass"><span id="passN">0</span> passed, </span>
<span class="fail"><span id="failN">0</span> failed, </span>
<span class="pending"><span id="pendingN">0</span> pending.</span>
<br/>
<br/>
<table id="results">
<tr>
<th>Test</th>
<th>Result</th>
<th>Time</th>
</tr>
</table>
</div>
<div id="foot"></div>
</div>
</body>
</html>