And now it’s all this

I just said what I said and it was wrong
Or was taken wrong

Hardware vs. software

March 19, 2026 at 1:28 PM by Dr. Drang

I’ve been thinking about the new Apple Studio Display lately, mainly in the context of Jason Snell’s review of it on Six Colors and his further discussion with Myke Hurley on Upgrade.

Jason’s primary complaint about the Studio Display isn’t its high price or how little it’s improved over the 2022 version. It’s that the base stand—the one you get for $1600—has no height adjustment. To get the ergonomic benefit of height adjustment, you need to buy either the VESA mount adapter (and an arm if you don’t already have one) or the exquisite height-adjustable stand, which is a $400 addition.

It’s hard to argue with Jason when he says this:

Apple claims it’s a champion of accessibility. But in my opinion, part of accessibility is ergonomics. Different people need displays at different heights, and we are all shaped differently. Apple’s continued insistence on shipping displays and iMacs that aren’t height-adjustable by default is frustrating. You spend all this money on a pricey Apple display and then, what, put it on an old dictionary? Meanwhile, even the cut-rate competition offers height adjustments.

The “old dictionary” comment reminded me that in the days of CRT monitors, I—and many of the people I worked with—used the CRC Handbook of Chemistry and Physics to bring our monitors up to the proper height. We all agreed it was the best use we’d ever gotten out of that book.

And that experience my friends and I had with the CRC Handbook points to an important fact about monitor height adjustment: for most people, it’s a set-it-and-forget-it feature. You get your monitor to a height that works well with your desk setup, and you don’t change it for ages. The smooth fingertip control Apple provides with its upgraded stand—while undoubtedly useful for some—isn’t the kind of ergonomic help that most customers need.

What Apple’s doing here is the opposite of what it does on the software side. Most Apple apps are built to be good enough for the great bulk of its users. People who need more—in a calendar, a mail client, a to-do manager, a spreadsheet, a word processor, and so on—go to third-party apps to get those extra features.

This has served both Apple and its customers well. Even those of us who consider ourselves power users aren’t power users across the whole gamut of computing. We use a mix of basic and advanced apps to match our needs. Apple doesn’t have to stay on the cutting edge of all its many software products, and we get free apps that handle a lot of what we do.

Maybe Apple thinks its basic stand has been designed to hit that sweet spot for the vast majority of its users. Maybe they’ve spent considerable time and money on studies of desks and chairs and torsos and have come up with a single monitor height that’s “just fine.” I hope not, because that money would’ve been better spent on a simpler and less beautiful height-adjustable stand.

---

A leap year inequality

March 15, 2026 at 6:22 PM by Dr. Drang

I’ve been working my way through the fourth edition of Reingold and Dershowitz’s Calendrical Calculations, and I want to talk about something I learned.

It’s a simple inequality that initially appears in the first chapter of the book and gets used several times thereafter. Here it is:

$$\ell (y+\mathrm{\Delta })\mathrm{mod}c<\ell$$

It’s first presented as a way to figure out how leap years are distributed. In some calendars—not the Gregorian—there’s a repeating cycle of $c$ years in which $\ell$ years are leap years. If the leap years are distributed as evenly as possible, then the years in which $y$ satisfies the inequality are the leap years. The $\mathrm{\Delta }$ is a sort of offset that determines the position within the cycle associated with Year 0, and the $\mathrm{mod}$ operator represents modulo division. In Python, that’s the % operator.

It’s helpful to look at examples. Let’s say we have a 7-year cycle with 2 leap years and 5 normal years in each cycle. The leap years have to be either 3 or 4 years apart. Here’s an example showing three cycles:

                       1 1 1 1 1 1 1 1 1 1 2 2
Year 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
Type N N N L N N L N N N L N N L N N N L N N L

For this, $c=7$, $\ell =2$, and $\mathrm{\Delta }=0$. You can plug the values into the inequality to show that it’s satisfied for years 4, 7, 11, 14, 18, 21, and so on.

Here’s a similar example. The only difference is the offset. In this case, $\mathrm{\Delta }=2$, and the leap years are years 2, 5, 9, 12, 16, 19, and so on.

                       1 1 1 1 1 1 1 1 1 1 2 2
Year 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
Type N L N N L N N N L N N L N N N L N N L N N

A practical example of this formula is with the Hebrew calendar. It has a 19-year cycle ($c=19$) with 7 leap years ($\ell =7$), and the offset is 11 years ($\mathrm{\Delta }=11$). The current year is 5786, for which

$$7(5786+11)\mathrm{mod}19=14\ge 7$$

so this is not a leap year. But for next year,

$$7(5787+11)\mathrm{mod}19=2<7$$

so it is a leap year and will have 13 months instead of 12. You can confirm this on any number of websites; the key is to note that 5787 has both an Adar I and an Adar II.

The Gregorian calendar has a 400-year cycle with 97 leap years, but those leap years are not distributed as evenly as possible, so the formula can’t be used. If it had been used, we’d have leap years typically every fourth year but occasionally every fifth year. Pope Gregory and his people must’ve thought that would be too tricky to deal with.

Surprisingly (to me, anyway), Reingold and Dershowitz do use this formula with the Gregorian calendar, but they use it with months instead of years. Think of the months in the Gregorian calendar as being either short or long. In a year, there are 5 short months and 7 long months, and they’re distributed like this:

                          1 1 1
        1 2 3 4 5 6 7 8 9 0 1 2
Month   J F M A M J J A S O N D
Length  L S L S L S L L S L S L

The positions of the long months correspond to our inequality with $c=12$, $\ell =7$, and $\mathrm{\Delta }=11$. Plug in those values, and you’ll see that the long months are 1, 3, 5, 7, 8, 10, and 12.

To calculate the day number within a year, it’s usually easiest to calculate the number of days in the preceding months and then add the day number within the current month. Today is March 15, so it’s Day $(31+28)+15=74$ of the year.

Instead of looping through the lengths of the preceding months, R&D use a formula based on our inequality to count the number of long months before the current month. That formula is

$$\lfloor \frac{\ell (m+\mathrm{\Delta }+1)}{c}\rfloor -\lfloor \frac{\ell \mathrm{\Delta }}{c}\rfloor$$

where the brackets without tops represent the floor function, i.e., the integer equal to or just below what’s inside the brackets.

Plugging in our values for $c$, $\ell$, and $\mathrm{\Delta }$ and doing some algebra, we get

$$\lfloor \frac{7m-2}{12}\rfloor$$

This is the number of long months in the year before the current month $m$.

If February had 30 days, the number of days in the months before the current month would be

$$30(m-1)+\lfloor \frac{7m-2}{12}\rfloor =\lfloor \frac{367m-362}{12}\rfloor$$

So to get the (Gregorian) day of the year, R&D calculate the day number as if February had 30 days and then subtract (if necessary) to account for February’s deficiency. In Python, the code looks like this:

python:
def day_of_year(year, month, day):
  year_day = (367 * month - 362) // 12 + day
  if month <= 2:
    return year_day
  elif leap_year(year):
    return year_day - 1
  else:
    return year_day - 2

where I’m assuming we already have a Boolean function leap_year to determine whether it’s a leap year or not. That’s not necessarily the most obvious code in the world, but it makes sense if you’ve gone through the derivation.

One last thing. Reingold is the co-author of a paper in which our inequality is connected to Euclid’s algorithm for calculating the greatest common divisor and Bresenham’s algorithm for plotting lines on bitmaps. Which is pretty cool.

---

Scientific American and Friday the 13th

March 13, 2026 at 6:48 PM by Dr. Drang

Scientific American has a fun little article today about the frequency of Friday the 13ths. It ends with this table,

and this true but overstated conclusion:

In other words, the 13th of a month will be a Friday more times than any other day of the week.

Well, yes, if you live to be 400 years old, you’ll see one more Friday the 13th than Wednesday the 13ths or Sunday the 13ths. Kind of a weird thing to focus on, though. I’m guessing you’ll have other worries by then.

But I shouldn’t be so snarky. A few years ago, I wrote a post that calculated the same set of Fri13 counts for a 400-year Gregorian cycle. I did the calculations in Mathematica and (of course) showed the code. Today, I did the same thing in Python,

python:
 1:  #!/usr/bin/env python
 2:  
 3:  from datetime import date
 4:  
 5:  f13s = [0]*7
 6:  for y in range(1800, 2200):
 7:    for m in range(1, 13):
 8:      wd = date(y, m, 13).weekday()
 9:      f13s[wd] += 1
10:  
11:  print(f13s)

and got a result of

[685, 685, 687, 684, 688, 684, 687]

for Monday through Sunday. This also matches the SciAm table.

Those of us who are alive now (and have realistic longevities) won’t live through any non-leap century years. For us, the calendar has and will repeat every 28 years (1461 weeks), and over every 28-year period in our lives, there will be 48 Fri13s, the same as the number of Mon13s, Tue13s, Wed13s, and so on.

Of course, few of us live exactly a multiple of 28 years. Personally, I’ve lived through 113 Fri13s so far, which is just under the number of Sun13s I’ve seen (114). So I’ve been lucky?

In a Friday the 13th post from way back in 2012, I talked about how Fri13s repeat within years because the number of days in certain month sequences is a multiple of 7. So if there’s a Fri13 in April, there will be another in July because

Apr + May + Jun
30  + 31  + 30  = 91

which is 13 weeks. The last time that happened was in 2018.

Similarly, if there’s a Fri13 in September, there will also be one in December because

Sep + Oct + Nov
30  + 31  + 30  = 91

That pair of Fri13s last happened in 2024.

There’s also an 8-month sequence that adds to a multiple of 7:

Mar + Apr + May + Jun + Jul + Aug + Sep + Oct
31  + 30  + 31  + 30  + 31  + 31  + 30  + 31  = 245

So there will be another Fri13 in November of this year.

The sequences above happen every year. In non-leap years only—this year, for example—a Fri13 in February will be followed by one in March. In leap years only, a Fri13 in January will be followed by one in April. That last happened in 2012.

I covered all these repeated Fri13s in that 2012 post. Today, I learned of a new repeat that spans certain year boundaries. If there’s a Fri13 in December of a non-leap year that’s followed by a leap year, there will be a Fri13 in March of that following year. That last happened in December of 2019 and March of 2020.

Superstitious or not, you have to admit March of 2020 was pretty unlucky.

---

Port ability

March 10, 2026 at 7:53 PM by Dr. Drang

I read Jason Snell’s review of the MacBook Neo this morning and was struck by this section on its two USB-C ports:

So Apple has done the work to put two USB-C ports on the Neo—and those ports reveal a bit more of the struggles Apple had in building this computer. Both of the USB-C ports will let you charge (which is good, because there’s no MagSafe), but only the one that’s furthest back is a fully functional USB 3 port with support for driving an external display at 4K, 60 frames per second. The closer-in USB port only offers USB 2 speeds. (The good news is that Apple has built alerts into macOS that will warn you if the device you’ve plugged into the slow port would be better off plugged into the faster one, so you won’t be transferring files slowly unnecessarily.)

It reminded me of Christina Warren’s angry Mastodon post about the Neo’s ports:

I’m just going to say that pointing out flaws in $600 and $700 laptops and having people instinctively respond “it’s not for real users, these buyers don’t know/care” is gross. Why should we make the assumption that those buyers don’t still deserve better, or at least on par with the 6 year old product it’s replacing that sold at the same price. Stop assuming people who don’t spend $1000+ on tech are imbeciles or deserve subpar options. No one in 2026 deserves a laptop with a single USB 3 port.

My first thought upon reading Christina’s complaint last week was “Why should I care about the configuration of a computer I’ll never buy?” Kind of a Republican thought, I admit, and I’m not proud of it. But I have many reasons to be disappointed by Apple, and I need to conserve my outrage. Christina’s much younger than I am and has deeper outrage reserves.

Jason pointed out the biggest problem with the low-speed port in his next paragraph:

Honestly, I’m more disappointed by the fact that mismatched ports can lead to user frustration—no, not that port, the other one—than I am about the one slow USB port.

Many Neo users will be too young to remember the joy of flipping USB-A plugs back and forth before getting the orientation right. Apple has updated that wonderful experience for the USB-C age.

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