mirror of
https://github.com/rn10950/RetroZilla.git
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446 lines
16 KiB
JavaScript
446 lines
16 KiB
JavaScript
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/* ***** BEGIN LICENSE BLOCK *****
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* Version: MPL 1.1/GPL 2.0/LGPL 2.1
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*
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* The contents of this file are subject to the Mozilla Public License Version
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* 1.1 (the "License"); you may not use this file except in compliance with
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* the License. You may obtain a copy of the License at
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* http://www.mozilla.org/MPL/
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*
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* Software distributed under the License is distributed on an "AS IS" basis,
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* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
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* for the specific language governing rights and limitations under the
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* License.
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*
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* The Original Code is Google Safe Browsing.
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*
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* The Initial Developer of the Original Code is Google Inc.
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* Portions created by the Initial Developer are Copyright (C) 2006
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* the Initial Developer. All Rights Reserved.
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*
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* Contributor(s):
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* Fritz Schneider <fritz@google.com> (original author)
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*
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* Alternatively, the contents of this file may be used under the terms of
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* either the GNU General Public License Version 2 or later (the "GPL"), or
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* the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
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* in which case the provisions of the GPL or the LGPL are applicable instead
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* of those above. If you wish to allow use of your version of this file only
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* under the terms of either the GPL or the LGPL, and not to allow others to
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* use your version of this file under the terms of the MPL, indicate your
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* decision by deleting the provisions above and replace them with the notice
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* and other provisions required by the GPL or the LGPL. If you do not delete
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* the provisions above, a recipient may use your version of this file under
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* the terms of any one of the MPL, the GPL or the LGPL.
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*
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* ***** END LICENSE BLOCK ***** */
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// This file implements the tricky business of managing the keys for our
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// URL encryption. The protocol is:
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//
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// - Server generates secret key K_S
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// - Client starts up and requests a new key K_C from the server via HTTPS
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// - Server generates K_C and WrappedKey, which is K_C encrypted with K_S
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// - Server resonse with K_C and WrappedKey
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// - When client wants to encrypt a URL, it encrypts it with K_C and sends
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// the encrypted URL along with WrappedKey
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// - Server decrypts WrappedKey with K_S to get K_C, and the URL with K_C
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//
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// This is, however, trickier than it sounds for two reasons. First,
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// we want to keep the number of HTTPS requests to an aboslute minimum
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// (like 1 or 2 per browser session). Second, the HTTPS request at
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// startup might fail, for example the user might be offline or a URL
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// fetch might need to be issued before the HTTPS request has
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// completed.
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//
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// We implement the following policy:
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//
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// - Firefox will issue at most two HTTPS getkey requests per session
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// - Firefox will issue one HTTPS getkey request at startup if more than 24
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// hours has passed since the last getkey request.
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// - Firefox will serialize to disk any key it gets
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// - Firefox will fall back on this serialized key until it has a
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// fresh key
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// - The front-end can respond with a flag in a lookup request that tells
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// the client to re-key. Firefox will issue a new HTTPS getkey request
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// at this time if it has only issued one before
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// We store the user key in this file. The key can be used to verify signed
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// server updates.
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const kKeyFilename = "kf.txt";
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/**
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* A key manager for UrlCrypto. There should be exactly one of these
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* per appplication, and all UrlCrypto's should share it. This is
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* currently implemented by having the manager attach itself to the
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* UrlCrypto's prototype at startup. We could've opted for a global
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* instead, but I like this better, even though it is spooky action
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* at a distance.
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* XXX: Should be an XPCOM service
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*
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* @param opt_keyFilename String containing the name of the
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* file we should serialize keys to/from. Used
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* mostly for testing.
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*
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* @param opt_testing Boolean indicating whether we are testing. If we
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* are, then we skip trying to read the old key from
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* file and automatically trying to rekey; presumably
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* the tester will drive these manually.
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*
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* @constructor
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*/
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function PROT_UrlCryptoKeyManager(opt_keyFilename, opt_testing) {
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this.debugZone = "urlcryptokeymanager";
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this.testing_ = !!opt_testing;
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this.base64_ = new G_Base64();
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this.clientKey_ = null; // Base64-encoded, as fetched from server
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this.clientKeyArray_ = null; // Base64-decoded into an array of numbers
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this.wrappedKey_ = null; // Opaque websafe base64-encoded server key
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this.rekeyTries_ = 0;
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// Don't do anything until keyUrl_ is set.
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this.keyUrl_ = null;
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this.keyFilename_ = opt_keyFilename ?
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opt_keyFilename : kKeyFilename;
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// Convenience properties
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this.MAX_REKEY_TRIES = PROT_UrlCryptoKeyManager.MAX_REKEY_TRIES;
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this.CLIENT_KEY_NAME = PROT_UrlCryptoKeyManager.CLIENT_KEY_NAME;
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this.WRAPPED_KEY_NAME = PROT_UrlCryptoKeyManager.WRAPPED_KEY_NAME;
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if (!this.testing_) {
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G_Assert(this, !PROT_UrlCrypto.prototype.manager_,
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"Already have manager?");
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PROT_UrlCrypto.prototype.manager_ = this;
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this.maybeLoadOldKey();
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}
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}
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// Do ***** NOT ***** set this higher; HTTPS is expensive
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PROT_UrlCryptoKeyManager.MAX_REKEY_TRIES = 2;
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// Base pref for keeping track of when we updated our key.
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// We store the time as seconds since the epoch.
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PROT_UrlCryptoKeyManager.NEXT_REKEY_PREF = "urlclassifier.keyupdatetime.";
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// Once a day (interval in seconds)
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PROT_UrlCryptoKeyManager.KEY_MIN_UPDATE_TIME = 24 * 60 * 60;
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// These are the names the server will respond with in protocol4 format
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PROT_UrlCryptoKeyManager.CLIENT_KEY_NAME = "clientkey";
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PROT_UrlCryptoKeyManager.WRAPPED_KEY_NAME = "wrappedkey";
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/**
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* Called by a UrlCrypto to get the current K_C
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*
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* @returns Array of numbers making up the client key or null if we
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* have no key
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*/
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PROT_UrlCryptoKeyManager.prototype.getClientKeyArray = function() {
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return this.clientKeyArray_;
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}
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/**
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* Called by a UrlCrypto to get WrappedKey
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*
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* @returns Opaque base64-encoded WrappedKey or null if we haven't
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* gotten one
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*/
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PROT_UrlCryptoKeyManager.prototype.getWrappedKey = function() {
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return this.wrappedKey_;
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}
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/**
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* Change the key url. When we do this, we go ahead and rekey.
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* @param keyUrl String
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*/
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PROT_UrlCryptoKeyManager.prototype.setKeyUrl = function(keyUrl) {
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// If it's the same key url, do nothing.
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if (keyUrl == this.keyUrl_)
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return;
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this.keyUrl_ = keyUrl;
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this.rekeyTries_ = 0;
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// Check to see if we should make a new getkey request.
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var prefs = new G_Preferences(PROT_UrlCryptoKeyManager.NEXT_REKEY_PREF);
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var nextRekey = prefs.getPref(this.getPrefName_(this.keyUrl_), 0);
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if (nextRekey < parseInt(Date.now() / 1000, 10)) {
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this.reKey();
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}
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}
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/**
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* Given a url, return the pref value to use (pref contains last update time).
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* We basically use the url up until query parameters. This avoids duplicate
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* pref entries as version number changes over time.
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* @param url String getkey URL
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*/
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PROT_UrlCryptoKeyManager.prototype.getPrefName_ = function(url) {
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var queryParam = url.indexOf("?");
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if (queryParam != -1) {
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return url.substring(0, queryParam);
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}
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return url;
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}
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/**
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* Tell the manager to re-key. For safety, this method still obeys the
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* max-tries limit. Clients should generally use maybeReKey() if they
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* want to try a re-keying: it's an error to call reKey() after we've
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* hit max-tries, but not an error to call maybeReKey().
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*/
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PROT_UrlCryptoKeyManager.prototype.reKey = function() {
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if (this.rekeyTries_ > this.MAX_REKEY_TRIES)
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throw new Error("Have already rekeyed " + this.rekeyTries_ + " times");
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this.rekeyTries_++;
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G_Debug(this, "Attempting to re-key");
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// If the keyUrl isn't set, we don't do anything.
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if (!this.testing_ && this.keyUrl_) {
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(new PROT_XMLFetcher()).get(this.keyUrl_,
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BindToObject(this.onGetKeyResponse, this));
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// Calculate the next time we're allowed to re-key.
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var prefs = new G_Preferences(PROT_UrlCryptoKeyManager.NEXT_REKEY_PREF);
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var nextRekey = parseInt(Date.now() / 1000, 10)
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+ PROT_UrlCryptoKeyManager.KEY_MIN_UPDATE_TIME;
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prefs.setPref(this.getPrefName_(this.keyUrl_), nextRekey);
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}
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}
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/**
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* Try to re-key if we haven't already hit our limit. It's OK to call
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* this method multiple times, even if we've already tried to rekey
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* more than the max. It will simply refuse to do so.
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*
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* @returns Boolean indicating if it actually issued a rekey request (that
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* is, if we haven' already hit the max)
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*/
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PROT_UrlCryptoKeyManager.prototype.maybeReKey = function() {
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if (this.rekeyTries_ > this.MAX_REKEY_TRIES) {
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G_Debug(this, "Not re-keying; already at max");
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return false;
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}
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this.reKey();
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return true;
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}
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/**
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* @returns Boolean indicating if we have a key we can use
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*/
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PROT_UrlCryptoKeyManager.prototype.hasKey_ = function() {
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return this.clientKey_ != null && this.wrappedKey_ != null;
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}
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/**
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* Set a new key and serialize it to disk.
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*
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* @param clientKey String containing the base64-encoded client key
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* we wish to use
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*
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* @param wrappedKey String containing the opaque base64-encoded WrappedKey
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* the server gave us (i.e., K_C encrypted with K_S)
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*/
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PROT_UrlCryptoKeyManager.prototype.replaceKey_ = function(clientKey,
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wrappedKey) {
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if (this.clientKey_)
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G_Debug(this, "Replacing " + this.clientKey_ + " with " + clientKey);
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this.clientKey_ = clientKey;
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this.clientKeyArray_ = this.base64_.decodeString(this.clientKey_);
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this.wrappedKey_ = wrappedKey;
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this.serializeKey_(this.clientKey_, this.wrappedKey_);
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}
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/**
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* Try to write the key to disk so we can fall back on it. Fail
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* silently if we cannot. The keys are serialized in protocol4 format.
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*
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* @returns Boolean indicating whether we succeeded in serializing
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*/
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PROT_UrlCryptoKeyManager.prototype.serializeKey_ = function() {
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var map = {};
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map[this.CLIENT_KEY_NAME] = this.clientKey_;
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map[this.WRAPPED_KEY_NAME] = this.wrappedKey_;
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try {
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var appDir = new PROT_ApplicationDirectory();
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if (!appDir.exists())
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appDir.create();
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var keyfile = appDir.getAppDirFileInterface();
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keyfile.append(this.keyFilename_);
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G_FileWriter.writeAll(keyfile, (new G_Protocol4Parser).serialize(map));
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return true;
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} catch(e) {
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G_Error(this, "Failed to serialize new key: " + e);
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return false;
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}
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}
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/**
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* Invoked when we've received a protocol4 response to our getkey
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* request. Try to parse it and set this key as the new one if we can.
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*
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* @param responseText String containing the protocol4 getkey response
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*/
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PROT_UrlCryptoKeyManager.prototype.onGetKeyResponse = function(responseText) {
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var response = (new G_Protocol4Parser).parse(responseText);
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var clientKey = response[this.CLIENT_KEY_NAME];
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var wrappedKey = response[this.WRAPPED_KEY_NAME];
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if (response && clientKey && wrappedKey) {
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G_Debug(this, "Got new key from: " + responseText);
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this.replaceKey_(clientKey, wrappedKey);
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} else {
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G_Debug(this, "Not a valid response for /getkey");
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}
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}
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/**
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* Attempt to read a key we've previously serialized from disk, so
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* that we can fall back on it in case we can't get one from the
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* server. If we get a key, only use it if we don't already have one
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* (i.e., if our startup HTTPS request died or hasn't yet completed).
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*
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* This method should be invoked early, like when the user's profile
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* becomes available.
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*/
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PROT_UrlCryptoKeyManager.prototype.maybeLoadOldKey = function() {
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var oldKey = null;
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try {
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var appDir = new PROT_ApplicationDirectory();
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var keyfile = appDir.getAppDirFileInterface();
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keyfile.append(this.keyFilename_);
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if (keyfile.exists())
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oldKey = G_FileReader.readAll(keyfile);
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} catch(e) {
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G_Debug(this, "Caught " + e + " trying to read keyfile");
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return;
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}
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if (!oldKey) {
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G_Debug(this, "Couldn't find old key.");
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return;
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}
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oldKey = (new G_Protocol4Parser).parse(oldKey);
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var clientKey = oldKey[this.CLIENT_KEY_NAME];
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var wrappedKey = oldKey[this.WRAPPED_KEY_NAME];
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if (oldKey && clientKey && wrappedKey && !this.hasKey_()) {
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G_Debug(this, "Read old key from disk.");
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this.replaceKey_(clientKey, wrappedKey);
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}
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}
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#ifdef DEBUG
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/**
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* Cheesey tests
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*/
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function TEST_PROT_UrlCryptoKeyManager() {
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if (G_GDEBUG) {
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var z = "urlcryptokeymanager UNITTEST";
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G_debugService.enableZone(z);
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G_Debug(z, "Starting");
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// Let's not clobber any real keyfile out there
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var kf = "keytest.txt";
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// Let's be able to clean up after ourselves
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function removeTestFile(f) {
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var appDir = new PROT_ApplicationDirectory();
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var file = appDir.getAppDirFileInterface();
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file.append(f);
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if (file.exists())
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file.remove(false /* do not recurse */);
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};
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removeTestFile(kf);
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var km = new PROT_UrlCryptoKeyManager(kf, true /* testing */);
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// CASE: simulate nothing on disk, then get something from server
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G_Assert(z, !km.hasKey_(), "KM already has key?");
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km.maybeLoadOldKey();
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G_Assert(z, !km.hasKey_(), "KM loaded non-existent key?");
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km.onGetKeyResponse(null);
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G_Assert(z, !km.hasKey_(), "KM got key from null response?");
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km.onGetKeyResponse("");
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G_Assert(z, !km.hasKey_(), "KM got key from empty response?");
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km.onGetKeyResponse("aslkaslkdf:34:a230\nskdjfaljsie");
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G_Assert(z, !km.hasKey_(), "KM got key from garbage response?");
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var realResponse = "clientkey:24:zGbaDbx1pxoYe7siZYi8VA==\n" +
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"wrappedkey:24:MTr1oDt6TSOFQDTvKCWz9PEn";
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km.onGetKeyResponse(realResponse);
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// Will have written it to file as a side effect
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G_Assert(z, km.hasKey_(), "KM couldn't get key from real response?");
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G_Assert(z, km.clientKey_ == "zGbaDbx1pxoYe7siZYi8VA==",
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"Parsed wrong client key from response?");
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G_Assert(z, km.wrappedKey_ == "MTr1oDt6TSOFQDTvKCWz9PEn",
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"Parsed wrong wrapped key from response?");
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// CASE: simulate something on disk, then get something from server
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km = new PROT_UrlCryptoKeyManager(kf, true /* testing */);
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G_Assert(z, !km.hasKey_(), "KM already has key?");
|
||
|
km.maybeLoadOldKey();
|
||
|
G_Assert(z, km.hasKey_(), "KM couldn't load existing key from disk?");
|
||
|
G_Assert(z, km.clientKey_ == "zGbaDbx1pxoYe7siZYi8VA==",
|
||
|
"Parsed wrong client key from disk?");
|
||
|
G_Assert(z, km.wrappedKey_ == "MTr1oDt6TSOFQDTvKCWz9PEn",
|
||
|
"Parsed wrong wrapped key from disk?");
|
||
|
var realResponse2 = "clientkey:24:dtmbEN1kgN/LmuEoYifaFw==\n" +
|
||
|
"wrappedkey:24:MTpPH3pnLDKihecOci+0W5dk";
|
||
|
km.onGetKeyResponse(realResponse2);
|
||
|
// Will have written it to disk
|
||
|
G_Assert(z, km.hasKey_(), "KM couldn't replace key from server response?");
|
||
|
G_Assert(z, km.clientKey_ == "dtmbEN1kgN/LmuEoYifaFw==",
|
||
|
"Replace client key from server failed?");
|
||
|
G_Assert(z, km.wrappedKey_ == "MTpPH3pnLDKihecOci+0W5dk",
|
||
|
"Replace wrapped key from server failed?");
|
||
|
|
||
|
// CASE: check overwriting a key on disk
|
||
|
|
||
|
km = new PROT_UrlCryptoKeyManager(kf, true /* testing */);
|
||
|
G_Assert(z, !km.hasKey_(), "KM already has key?");
|
||
|
km.maybeLoadOldKey();
|
||
|
G_Assert(z, km.hasKey_(), "KM couldn't load existing key from disk?");
|
||
|
G_Assert(z, km.clientKey_ == "dtmbEN1kgN/LmuEoYifaFw==",
|
||
|
"Replace client on from disk failed?");
|
||
|
G_Assert(z, km.wrappedKey_ == "MTpPH3pnLDKihecOci+0W5dk",
|
||
|
"Replace wrapped key on disk failed?");
|
||
|
|
||
|
// Test that we only fetch at most two getkey's per lifetime of the manager
|
||
|
|
||
|
km = new PROT_UrlCryptoKeyManager(kf, true /* testing */);
|
||
|
km.reKey();
|
||
|
for (var i = 0; i < km.MAX_REKEY_TRIES; i++)
|
||
|
G_Assert(z, km.maybeReKey(), "Couldn't rekey?");
|
||
|
G_Assert(z, !km.maybeReKey(), "Rekeyed when max hit");
|
||
|
|
||
|
removeTestFile(kf);
|
||
|
|
||
|
G_Debug(z, "PASSED");
|
||
|
|
||
|
}
|
||
|
}
|
||
|
#endif
|