Windows Secure Time Seeding resets clocks months or years off the correct time.
STS (Secure Time Seeding) uses server time from SSL handshakes, which is fine when talking to other Microsoft servers, but other implementations put random data in that field to prevent fingerprinting.
This bug has created havocs for me. We had a “last synchronized” time stamp persisted to a DB so that the system was able to robustly deal with server restarts / bootstrapping on new environments.
The synchronization was used to continuously fetch critical incident and visualize them on a map. The data came through a third party api that broke down if we asked for too much data at a time, so we had to reason about when we fetched data last time, and only ask for new updates since then.
Each time the synchronization ran, it would persist an updated time stamp to the DB.
Of course this routine ran just as the server jumped several months into the feature for a few minutes. After this, the last run time stamp was now some time next year. Subsequent runs of the synchronization routine never found any updates as the date range it asked for didn’t really make sense.
It just ran successfully without finding any new issues. We were quite happy about it. It took months before we figured out we actually had a mayor discrepancy in our visualization map.
We had plenty of unit tests, integration tests, and system tests. We just didn’t think of having one that checked whether the server had time traveled to the future or not.
Reminds me of a "bug" in a genealogy software which crashed for a client. Turns out the client had incest and entering the relation in the software caused a loop in the family tree.
While the root issue was still unknown, we actually wrote one. It sort of made sense. Check that the date from isn’t later than date to in the generated range used for the synchronization request. Obviously. You never know what some idiot future coder (usually yourself some weeks from now) would do, am I right?
However, it was far worse to write the code that fulfilled the test. In the very same few lines of code, we fetched the current date from time.now() plus some time span as date.to, fetched the last synchronization timestamp from db as date.from, and then validated that date.from wasn’t greater than date.to, and if so, log an error about it.
The validation code made no logic sense when looking at it.
I've read the stuff on STS and my first thought was: How can anyone be so stupid to try such a loony concept and still be able to create a working piece of code?
A few months ago, an engineer in a data center in Norway encountered some perplexing errors that caused a Windows server to suddenly reset its system clock to 55 days in the future.
“With these updated routing tables, a lot of people were unable to make calls, as we didn't have a correct state!” the engineer, who asked to be identified only by his first name, Simen, wrote in an email.
Simen had experienced a similar error last August when a machine running Windows Server 2019 reset its clock to January 2023 and then changed it back a short time later.
Windows systems with clocks set to the wrong time can cause disastrous errors when they can’t properly parse timestamps in digital certificates or they execute jobs too early, too late, or out of the prescribed order.
The mechanism, Microsoft engineers wrote, “helped us to break the cyclical dependency between client system time and security keys, including SSL certificates.”
Simen and Ken, who both asked to be identified only by their first names because they weren’t authorized by their employers to speak on the record, soon found that engineers and administrators had been reporting the same time resets since 2016.