And in particular, I wanted to underscore this point: software is hard, even for experts. Experts have the same struggles that beginners do.

I used this tweet as an illustration:

I love the raw emotion on the two boys' faces. They perfectly illustrate both the frustration and exhilaration of writing software.

But here's what beginners might not understand: beginners think beginners feel the frustration, and experts feel the exhilaration. As any expert will tell you, experts feel plenty of frustration. They feel like that left-hand kid a lot.

The difference between beginners and experts is that experts are familiar with that frustration. They encounter it all the time, as they deal with new unfamiliar technologies, or a thorny bug, or just when they are too tired to tackle the problem before them. They know the frustration is because they are facing a challenging problem. They know it isn't a reflection of their self-worth or abilities. Experts know the feeling will pass, and they have techniques for dealing with the frustration.

When beginners get frustrated, they can start to worry that they are not cut out for software, or they are dumb, or that everyone else gets it and they don't.

The good news for beginners is: this isn't about you. Software is difficult. We build layer upon layer of leaky abstractions, of higher and higher realms of virtualization and complexity. There's no natural limit to how high our towers of complexity can go, so we are forced to try to understand them, or tame them, and it's very hard. Our languages and tools are obscure and different and new ones are invented all the time. Frustration is inevitable.

The bad news for beginners is: this feeling won't stop. If you do your software career right, then you will always be a newb at something. Sure, you can master a specialty, and stick with it, but that can get boring. And that specialty might dwindle away leaving you stranded.

You will be learning new things forever. That feeling of frustration is you learning a new thing. Get used to it.

A quick spin around the latest alternatives showed the usual spectrum of possibilities, ranging from perl hackers implementing rsync themselves, to slick consumer tools. I need to have something working well not just on my computer, but others in my family, so I went the consumerish route.

Arq backing up to Wasabi seems like a good choice for polish and price.

One thing I always struggle with: how to ensure my stuff is backed up, without needlessly copying around all the crap that ends up in my home directory that I don't need backed up. On a Mac, the ~/Library directory has all sorts of stuff that I think I don't need to copy around. Do I need these?:

• Library/Application Support
• Library/Caches
• Library/Containers

I add these directories to the exclusions. Should my Dropbox folder get backed up? Isn't that what Dropbox is already doing?

Then as a developer, there's tons more to exclude. Running VirtualBox? You have have a 10Gb disk image somewhere under your home. I have something like 20,000 .pyc files. The .tox directory for coverage.py is 350Mb.

So I also exclude these:

• .git
• .hg
• .svn
• .tox
• node_modules
• .local
• .npm
• .vagrant.d
• .vmdk
• .bundle
• .cache
• .heroku
• .rbenv
• .gem
• *.pyc
• *.pyo
• *$py.class

Of course, as a native Mac app for consumers, Arq doesn't provide a way that I can supply all these once, I have to fiddle with GUI + and - buttons, and enter them one at a time...

Lastly, some files don't seem comfortable with backups. Thunderbird's storage files are large, and while Arq copies only certain byte ranges, they still amount to about 300Mb each time. Should I even back up my email? Should I still be using Thunderbird? Too many uncertainties....

I've only listened to a small part of it. Getting ideas out verbally is different than in writing: there's no chance to go back and edit. To me, I sound a bit halting, because I was trying to get the words and sentences right in my head before I said them. I hope it sounds OK to others. Also, I think I said "dudes" and "guy" when I could have chosen more neutral words, sorry about that.

Tobias has been doing a great job with this podcast. It's not easy to consistently put out good content (I hate that word) on a regular schedule. He's been finding interesting people and giving them a good place to talk about their Python world, whatever that means to them.

BTW, this is my second time on Podcast.__init__, and it seems I never mentioned the first time in this blog, so here it is, from two years ago: Episode 5: Ned Batchelder. The focus then was the user group I organize, Boston Python, so a completely different topic:

And in the unlikely case that you want yet more of my dulcet tones, I was also on the Python Test podcast, mentioned in this blog post: The Value of Unit Tests.

One of the things that surprised me when I looked back is how many pictures I took in a very small area, one that I would have thought of as uninteresting: the few blocks between where I swim in the morning, and where I work. Of the 197 pictures I took in the last year, 38 of them are from that neighborhood:

I'm not saying these are all masterpieces. But I wouldn't have thought to take them at all if I hadn't been explicitly looking for something interesting to shoot.

Look around you: not much is truly uninteresting.

I found a solution, though I'm surprised I didn't find it described elsewhere.

The challenges have nothing to do with the two-dimensional aspect, and everything to do with using floats, so for the purposes of explaining, I'll simplify the problem to one-dimensional points. I'll have a class with a single float in it to represent my points.

First let's look at what happens with a simple dict:

>>> from collections import namedtuple
>>> Pt = namedtuple("Pt", "x")
>>>
>>> d = {}
>>> d[Pt(1.0)] = "hello"
>>> d[Pt(1.0)]
'hello'
>>> d[Pt(1.000000000001)]
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
KeyError: Pt(x=1.000000000001)


As long as our floats are precisely equal, the dict works fine. But as soon as we get two floats that are meant to represent the same value, but are actually slightly unequal, then the dict is useless to us. So a simple dict is no good.

To get the program running at all, I used a dead-simple structure that I knew would work: a list of key/value pairs. By defining __eq__ on my Pt class to compare with some fuzz, I could find matches that were slightly unequal:

>>> class Pt(namedtuple("Pt", "x")):
...     def __eq__(self, other):
...         return math.isclose(self.x, other.x)
...
>>> def get_match(pairs, pt):
...     for pt2, val in pairs:
...         if pt2 == pt:
...             return val
...     return None
...
>>> pairs = [
...     (Pt(1.0), "hello"),
...     (Pt(2.0), "goodbye"),
... ]
>>>
>>> get_match(pairs, Pt(2.0))
'goodbye'
>>> get_match(pairs, Pt(2.000000000001))
'goodbye'


This works, because now we are using an inexact closeness test to find the match. But we have an O(n) algorithm, which isn't great. Also, there's no way to define __hash__ to match that __eq__ test, so our points are no longer hashable.

Trying to make things near each other be equal naturally brings rounding to mind. Maybe that could work? Let's define __eq__ and __hash__ based on rounding the value:

>>> class Pt(namedtuple("Pt", "x")):
...     def __eq__(self, other):
...         return round(self.x, 6) == round(other.x, 6)
...     def __hash__(self):
...         return hash(round(self.x, 6))
...
>>> d = {}
>>> d[Pt(1.0)] = "apple"
>>> d[Pt(1.0)]
'apple'
>>> d[Pt(1.00000001)]
'apple'


Nice! We have matches based on values being close enough, and we can use a dict to get O(1) behavior. But:

>>> d[Pt(1.000000499999)] = "cat"
>>> d[Pt(1.000000500001)]
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
KeyError: Pt(x=1.000000500001)


Because rounding has sharp edges (ironically!), there will always be pairs of numbers arbitrarily close together that will round away from each other.

So rounding was close, but not good enough. We can't guarantee that we won't have these pairs of numbers that are in just the wrong place so that rounding will give the wrong answer.

I thought about other data structures: bisection in a sorted list sounded good (O(log n)), but that requires testing for less-than, and I wasn't sure how the fuzziness would affect it. Reading about other geometric algorithms lead to things like k-d trees, which seem exotic and powerful, but I didn't see how to put them to use here.

Then early one morning when I wasn't even trying to solve the problem, I had an idea: round the values two different ways. The problem with rounding was that it failed for values that straddled the rounding boundary. We can round twice, the second time with half the rounding window added, so the two are half out of phase. That way, if the first rounding separates the values, the second rounding won't.

We can't use double-rounding to produce a canonical value for comparisons and hashes, so instead we make a new data structure. We'll use a dict to map points to values, just as we did originally. A second dict will map rounded points to the original points. When we look up a point, if it isn't in the first dict, then round it two ways, and see if either is in the second dict. If it is, then we know what original point to use in the first dict.

That's a lot of words. Here's some code:

class Pt(namedtuple("Pt", "x")):
    # no need for special __eq__ or __hash__
    pass

class PointMap:
    def __init__(self):
        self._items = {}
        self._rounded = {}

    ROUND_DIGITS = 6
    JITTERS = [0, 0.5 * 10 ** -ROUND_DIGITS]

    def _round(self, pt, jitter):
        return Pt(round(pt.x + jitter, ndigits=self.ROUND_DIGITS))

    def __getitem__(self, pt):
        val = self._items.get(pt)
        if val is not None:
            return val

        for jitter in self.JITTERS:
            pt_rnd = self._round(pt, jitter)
            pt0 = self._rounded.get(pt_rnd)
            if pt0 is not None:
                return self._items[pt0]

        raise KeyError(pt)

    def __setitem__(self, pt, val):
        self._items[pt] = val
        for jitter in self.JITTERS:
            pt_rnd = self._round(pt, jitter)
            self._rounded[pt_rnd] = pt


This is now O(1), wonderful! I was surprised that I couldn't find something like this already explained somewhere. Perhaps finding values like I need to do is unusual? Or this is well-known, but under some name I couldn't find? Or is it broken in some way I can't see?

The proof is in On Triangular Fibonacci Numbers, a dense 10-page excursion into number theory I don't understand.

While I couldn't follow the proof, I can partially test the claim empirically, which leads to fun with Python and itertools, something which is much more in my wheelhouse.

I started by defining generators for triangular numbers and Fibonacci numbers:

def tri():
    """Generate an infinite sequence of triangular numbers."""
    n = 0
    for i in itertools.count(start=1):
        n += i
        yield n
        
print(list(itertools.islice(tri(), 50)))


[1, 3, 6, 10, 15, 21, 28, 36, 45, 55, 66, 78, 91, 105, 120, 136, 153, 171,
 190, 210, 231, 253, 276, 300, 325, 351, 378, 406, 435, 465, 496, 528, 561,
 595, 630, 666, 703, 741, 780, 820, 861, 903, 946, 990, 1035, 1081, 1128,
 1176, 1225, 1275]


def fib():
    """Generate an infinite sequence of Fibonacci numbers."""
    a, b = 1, 1
    while True:
        yield a
        b, a = a, a+b
        
print(list(itertools.islice(fib(), 50)))


[1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, 377, 610, 987, 1597, 2584,
 4181, 6765, 10946, 17711, 28657, 46368, 75025, 121393, 196418, 317811,
 514229, 832040, 1346269, 2178309, 3524578, 5702887, 9227465, 14930352,
 24157817, 39088169, 63245986, 102334155, 165580141, 267914296, 433494437,
 701408733, 1134903170, 1836311903, 2971215073, 4807526976, 7778742049,
 12586269025, 20365011074]


The Fibonacci sequence grows much faster!

My first impulse was to make two sets of the numbers in the sequences, and intersect them, but building a very large set took too long. So instead I wrote a function that took advantage of the ever-increasing nature of the sequences to look for equal elements in two monotonic sequences:

def find_same(s1, s2):
    """Find equal elements in two monotonic sequences."""
    try:
        i1, i2 = iter(s1), iter(s2)
        n1, n2 = next(i1), next(i2)
        while True:
            while n1 < n2:
                n1 = next(i1)
            if n1 == n2:
                yield n1
                n1 = next(i1)
            while n2 < n1:
                n2 = next(i2)
            if n1 == n2:
                yield n1
                n1 = next(i1)
    except StopIteration:
        return


And a function to cut off an infinite sequence once a certain ceiling had been reached:

def upto(s, n):
    """Stop a monotonic sequence once it gets to n."""
    for i in s:
        if i > n:
            return
        yield i


Now I could ask, what values less than quadrillion are in both the triangular numbers and the Fibonacci sequence?:

>>> list(find_same(upto(fib(), 1e15), upto(tri(), 1e15)))
[1, 3, 21, 55]


This doesn't prove the claim for all numbers, but it shows that 55 is the largest number under a quadrillion that is in both sequences.

Another way to do this is to take advantage of the asymmetry in growth rate. The Fibonacci sequence up a quadrillion is only 72 elements. Make that a set, then examine the triangular numbers up to quadrillion and keep the ones that are in the Fibonacci set. And I'm certain there are other techniques too.

I can't explain why, but composable generators please me. This was fun. :)

1 1 2 3 5 8 13 21 34 55 ...

55 is a triangular number:

1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9 + 10 = 55

It is the largest number that is both Fibonacci and triangular.

It is also a Kaprekar number:

55² = 3025 and 30+25 = 55

I have some Markdown files to convert to ReStructured Text. Pandoc does a really good job. But it chooses a different order for heading punctuation than our house style, and I didn't see a way to control it.

But it was easy to write a small thing to do the small thing:

import re
import sys

# The order we want our heading rules.
GOOD_RULES = '#*=-.~'

# A rule is any line of all the same non-word character, 3 or more.
RULE_RX = r"^([^\w\d])\1\1+$"

def rerule_file(f):
    rules = {}
    for line in f:
        line = line.rstrip()
        rule_m = re.search(RULE_RX, line)
        if rule_m:
            if line[0] not in rules:
                rules[line[0]] = GOOD_RULES[len(rules)]
            line = rules[line[0]] * len(line)
        print(line)

rerule_file(sys.stdin)


If you aren't conversant in .rst: there's no fixed order to which punctuation means which level heading. The first rule encountered is heading 1, the next style found is heading 2, and so on.

There might be other ways to do this, but this makes me happy.

I went looking for a thing that I figured must exist: a Mac app that would display that information in a dock icon. I already have a dock clock. I found a dock battery indicator, though it tried so hard to be cute and pictorial, I couldn't tell what it was telling me.

Asking around, I got a recommendation for GeekTool. It lets you draw a panel on your desktop, and then draw in the panel with the output of a script. Now the ball was back in my court: I could build my own thing.

I'd long ago moved the dock to the left side of the screen (again, to use all the vertical space for my own stuff.) This left a small rectangle of desktop visible at the upper left and lower left, even with maximized windows. I drew a panel in the upper left of the desktop, and set it to run this script every five seconds:

#!/usr/bin/env python3.6

import datetime
import re
import subprocess

def block_eighths(eighths):
    """Return the Unicode string for a block of so many eighths."""
    assert 0 <= eighths <= 8
    if eighths == 0:
        return "\u2003"
    else:
        return chr(0x2590 - eighths)

def gauge(percent):
    """Return a two-char string drawing a 16-part gauge."""
    slices = round(percent / (100 / 16))
    b1 = block_eighths(min(slices, 8))
    b2 = block_eighths(max(slices - 8, 0))
    return b1 + b2

now = datetime.datetime.now()
print(f"{now:%-I:%M\n%-m/%-d}")

batt = subprocess.check_output(["pmset", "-g", "batt"]).decode('utf8').splitlines()
m = re.search(r"\d+%", batt[1])
if m:
    level = m.group(0)
    batt_percent = int(level[:-1])
else:
    level = "??%"
if "discharging" in batt[1]:
    arrow = "\u25bc"        # BLACK DOWN-POINTING TRIANGLE
elif "charging" in batt[1]:
    arrow = "\u25b3"        # WHITE UP-POINTING TRIANGLE
else:
    arrow = ""

print(level + arrow)
print(gauge(batt_percent) + "\u2578")   # BOX DRAWINGS HEAVY LEFT

vol = subprocess.check_output(["osascript", "-e", "get volume settings"]).decode('utf8')
m = re.search(r"^output volume:(\d+), .* muted:(\w+)", vol)
if m:
    level, muted = m.groups()
    if muted == 'true':
        level = "\u20e5"        # COMBINING REVERSE SOLIDUS OVERLAY
    print(f"\u24cb{level}")     # CIRCLED LATIN CAPITAL LETTER V

# For debugging: output the raw data, but pushed out of view.
print(f"{'':30}{batt}")
print(f"{'':30}{vol}")


This displays the time, date, battery level (both numerically and as a crudely drawn battery gauge), whether the battery is charging or discharging, and the volume level:

BTW, if you are looking for Python esoterica, there are a few little-known things going on in this line:

print(f"{now:%-I:%M\n%-m/%-d}")


Finding Unicode characters to represent things was a bit of a challenge. I couldn't find exactly what I need for the right tip of the battery gauge, but it works well enough.

Geektool also does web pages, though in a quick experiment I couldn't make it do something useful, so I stuck with text mode. There also seem to be old forks of Geektool that offer text colors, which could be cool, but it started to feel a bit off-the-path.

This works great for what it does.