You’re spot on. The vast majority of news coverage and “hype” from the general public relating to Y2K was all horse shit, but there were critical systems that did have issues and needed some work.

For the most part, the whole 19100 issue was a display bug, and likely wouldn’t have caused problems, and the same for 1900… Those are examples that people generally saw at banks and whatnot, it would, for the most part, look weird, but for the most part, wouldn’t create any actual problems. It would just be confusing for a while until the system caught up.

I think there’s a few examples of companies missing the January 1st deadline and ending up with stuff marked as January 1900 for a bit. Otherwise they didn’t have any significant issues.

Anything that involves a legally binding agreement would be critical though. Since the date is part of the agreement terms, it would need to be correct, and shown correctly.

Unless the “bug” literally crashed the system (which, it really should not have in most cases), like in your example, or it was connected to a legal contract, then it really wasn’t that big of a problem.

The media, and people in general kept going on about it like they knew what the technical problem was, and it was always just conjecture and banter that made people worry unnecessarily.

What I’m trying to say is that Y2K was something that needed to be fixed but the likelihood that it would affect any singular person in society was very small. Those that were going to be affected, generally knew who they were and they were taking the steps required to fix the problem.

Planes crashing out of the sky wouldn’t have been inconceivable. Say you have two air traffic control systems that are synchronizing - one handles dates with a modulo 100 (00-99, i.e. 1900-1999), another handles them in epoch time. All of a sudden the two reported time + positions of two different planes don’t match up by a century, and collision projection software doesn’t work right. I’ve seen nastier bugs than that, in terms of conceptual failure.

At no point is that a theory about a “conspiracy” either, IDK why you’re bandying that term around.

The Microsoft Zune had a y2k9 bug caused by a lingering clock issue from leap year from the extra day in February 2008 that caused them to crash HARD on Jan 1, 2009. I remember It being a pretty big PITA getting it back up and running.

The comment you’re replying to is really frustrating to me. It annoys me when people are so arrogant but also wrong. Do they live in a perfect world where nobody stores dates as ISO 8601 strings? I’ve seen that tons of times. Sometimes, it may even be considered the appropriate format when using stuff like JSON based formats.

I would hope that these kinds of parsers are not used in critical applications that could actually lead to catastrophic events, that’s definitely different to Y2K. There would be bugs, yes, but quite fixable ones.

Regarding Y2K, it wasn’t horse shit - thousands upon thousands of developer hours were invested to prevent these issues before they occurred. Had they not done so, a bunch of systems would have broken, because parsing time isn’t just about displaying 19 or 20.

“There’s no glory in prevention”. I guess it’s hard to grasp nowadays, that mankind at some point actually tried to stop catastrophies from happening and succeeded

Years

YYYY

±YYYYY

ISO 8601 prescribes, as a minimum, a four-digit year [YYYY] to avoid the year 2000 problem. It therefore represents years from 0000 to 9999, year 0000 being equal to 1 BC and all others AD, similar to astronomical year numbering. However, years before 1583 (the first full year following the introduction of the Gregorian calendar) are not automatically allowed by the standard. Instead, the standard states that “values in the range [0000] through [1582] shall only be used by mutual agreement of the partners in information interchange”.[20]

To represent years before 0000 or after 9999, the standard also permits the expansion of the year representation but only by prior agreement between the sender and the receiver.[21] An expanded year representation [±YYYYY] must have an agreed-upon number of extra year digits beyond the four-digit minimum, and it must be prefixed with a + or − sign[22] instead of the more common AD/BC (or CE/BCE) notation; by convention 1 BC is labelled +0000, 2 BC is labeled −0001, and so on.[23]

If you’re being handed a string 2022424-12-19T14:44:39Z, and told it’s ISO-8601, you should be able to figure it out. Really, a decent parser should be able to recognize that on its own (just use {4,} instead of {4} in regex). It does mean that non-hyphenated YYYYMMDD shouldn’t be used (I typically never see them encoded that way) - but even if you did, you’d just do (\d{4,})(\d{2})(\d(2}).

64 bits value

… About that… https://en.wikipedia.org/wiki/Year_2038_problem

That has forever been the fallacy.

The poor won’t die in the apocalypse leaving only the rich behind. The poor will die, and the rich will be faced with the harsh reality that they needed an army of poor working under them to sustain themselves, leading them to all die within the generation.

Yo I dunno what you made me do but now I got the y10k virus, help

Fucking forgot to use a time dilation safe type for storing my time variables

Don’t worry, we’ll be extinct soon, hopefully. Maybe even before int32_t runs out. Unfortunately not soon enough to stop the humans impact on earth before the worst damage is done.

Yes, there are random systems using every kind of smart or brain-dead option out there.

But the 2038 problem impacts the previous standard, and the current one will take ages to fail. (No, it’s not 33000, unless you are using some variant of the standard that counts nanoseconds instead of seconds. Those usually have more bits nowadays, but some odd older systems do it on the same 64 bits from the standard.)

I’m pretty certain most of my work inevitably ends up being related to a time issue

Just start over at year 0000 AT (after ten thousand)

The ISO time standard will certainly need to be redone

33,000 would come from other programs that store the year as a 16-bit signed int. Year 32,768, to be precise.

A common method of storing dates is the number of seconds since midnight on Jan 1, 1970 (which was somewhat arbitrarily chosen).

A 32-bit signed integer means it can store numbers between 2³¹ through 2³¹ - 1 (subtracting one comes from zero being effectively a positive number for these purposes). 2³¹ - 1 seconds added to Jan 1, 1970 gets you to Jan 19, 2038.

The solution is to jump to 64-bit integers, but as with Y2K, there’s a lot of old systems that need to be updated to 64-bit integers (and no, they don’t necessarily have to have 64-bit CPUs to make that work). For the most part, this has been done already. That would put the date out to 292,277,026,596 CE. Which is orders of magnitude past the time for the sun to turn into a red giant.

Unix computers store time in seconds that have passed since january first 1970. one there have been too many seconds since 1970, it starts breaking. ‘signed’ is a way to store negative numbers in binary. the basics of it are: when the leftmost bit is a 1, it’s a negative number (and then you do some other things to the rest of the number so that it acts like a negative number) so when there have been 09999999 seconds since 1970, if there’s one more second it’ll be 10000000, which a computer sees as -9999999.