Planet Twisted

You’re applying for jobs, you’re hoping to get an offer soon—and when you do you’ll have to face the scary issue of negotiation.

If you read a negotiation guide like Valerie Aurora’s HOWTO (and you should!) you’re told you need to negotiate: you need to ask for more. And that’s good advice.

The problem is that asking for more is scary: it feels confrontational, your body will kick in with an unhelpful adrenaline surge, it’s just not comfortable. And honestly, given you only negotiate your salary every few years, that adrenaline surge probably isn’t going to go away.

But I think you can get past that and negotiate anyway—by embracing your inner 6-year old. In particular, a 6-year old negotiating for snacks on a playdate.

Snack time!

Let’s set the scene.

A 6-year old named Emma is visiting her friend Jackson, and now it’s time for a snack. Jackson’s parent—Michael—now needs to feed Emma.

Michael would prefer the children not eat crackers, but he has a problem. Michael has some authority over Jackson since he’s his parent, and some knowledge of what Jackson is willing to eat. So he can say “you’re eating one of these mildly healthy snacks” and that’s the end of it.

But Emma is just visiting: Michael has less authority, less knowledge, and a hungry 6-year old is Bad News. So Michael comes up with an acceptable range of snacks, and tries his best to steer towards the ones he considers healthier.

The conversation goes something like this:

Michael: “Would you like some fruit?”

Emma: blank stare.

Michael: “How about same cheese?”

Emma: shakes her head.

Michael: “Yogurt?”

Emma: shakes her head.

Michael: “Crackers?”

Emma and Jackson: “Yes!”

Michael has committed to feeding Emma something, he doesn’t want her to go hungry—but he doesn’t have the normal leverage he has as a parent. As a result, Emma can just stall until she gets what she wants. Particularly enterprising children will ask for candy (even when they would never get candy at home!), but stalling seems well within the capacity of most 6-year olds.

Salary time!

The dynamic of hiring a new employee is surprisingly similar.

Whoever is making the offer—HR, an internal recruiter, or the hiring manager—has already committed to hiring you. They’ve decided: they had interviews and meetings and they want to get it over with and just get you on board.

So they come up with an acceptable salary range, and offer you the low end of the range. If you accept that, great. And if you say “can you do better?”

Well, they’ve already decided on their acceptable salary range: they’ll just move up within that range. They’re not insulted, they’re used to this. They’re not horrified at a hole in their budget, this is still within their acceptable range.

You went from fruit to crackers, and they can live with that. All you have to do is ask.

Embrace your inner 6-year old

Much of what determines your salary happens before you get the offer, when the decision is made about what salary range to offer you.

You can influence this by the language on your resume, by how you present yourself, how you interview, and by noting you have competing offers. It may not feel like negotiation, but it’s all part of the process—and while it’s a set of skills you can master as an adult, that part is far beyond what your 6-year old self could do.

But the actual conversation about salary? Pretend you’re 6, pretend it’s a snack, and ask for more—chances are you’ll get some delicious crackers.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

JSON is a useful format. It might not be ideal for hand-editing, but it does have the benefit that it can be hand-edited, and it is easy enough to manipulate programmatically.

For this reason, it is likely that at some point or another, checking in a JSON file into your repository will seem like a good idea. Perhaps it is even beyond your control: some existing technology uses JSON as a configuration file, and the easiest thing is to go with it.

It is useful to still keep the benefit of programmatic manipulation. For example, if the JSON file encodes a list of numbers, and we want to add 1 to every even number, we can do:

with open("myfile.json") as fp:
    content = json.load(fp)
content = [x + (2 % i) for i, x in enumerate(content)]
with open("myfile.json", "w") as fp:
    json.dumps(fp, content)

However, this does cause a problem: presumably, before, the list was formatted in a visually-pleasing way. Having dumped it, now the diff is unreadable -- and hard to audit visually.

One solution is to enforce consistent formatting.

For example, using pytest, we can write the following test:

def test_formatting():
    with open("myfile.json") as fp:
        raw = fp.read()
    content = json.loads(raw)
    redumped = json.dumps(content, indent=4) + "\n"
    assert raw == redumped

Assuming we gate merges to the main branches on passing tests, it is impossible to check in something that breaks the formatting. Automated programs merely need to remember to give the right options to json.dumps. However, what happens when humans make mistakes?

It turns out that Python already has a command-line tool to reformat:

$ python -m json.tool myfile.json > myfile.json.formatted
$ mv myfile.json.formatted myfile.json

A nice test failure will remind the programmer of this trick, so that it is easy to do and check in.

A reader of my newsletter wrote in, talking about the problem of finding a job with work/life balance in Silicon Valley:

It seems like us software engineers are in a tough spot: companies demand a lot of hard work and long hours, and due to the competitiveness here in Silicon Valley, you have to go along with it (or else there’s some bright young Stanford grad just dying to work all nighters on Red Bull to take your place).

But they throw you aside once the company has become established and they no longer need the “creative” types.

In short, how do you get a job with work/life balance when you’re competing against people willing to work long hours?

All nighters make for bad software

The starting point is realizing that working long hours makes you a much less productive employee, to the point that your total output will actually decrease (see Evan Robinson on crunch time). If you want to become an effective and productive worker, you’re actually much better off working normal hours and having a personal life than working longer hours.

Since working shorter hours makes you more productive, that gives you a starting point for why you should be hired.

Instead of focusing on demonstrative effort by working long hours, you can focus on identifying and solving valuable problems, especially the bigger and longer term problems that require thought and planning to solve.

Picking the right company

Just because you’re a valuable, productive programmer doesn’t mean you’re going to get hired, of course. So next you need to find the right company.

You can imagine three levels of managerial skill:

• Level 1: These managers have no idea how to recognize effective workers, so they only judge people by hours worked.
• Level 2: These managers can recognize effective workers, but don’t quite know how to create a productive culture. That means if you choose work long hours they won’t stop you, however pointless these long hours may be. But, they won’t force you work long hours so long as you’re doing a decent job.
• Level 3: These managers can recognize effective workers and will encourage a productive culture. Which is to say, they will explicitly discourage working long hours except in emergencies, they will take steps to prevent future emergencies, etc..

When you look for a job you will want to avoid Level 1 managers. However good your work, they will be happy to replace you with someone incompetent so long as they can get more hours out of them. So you’ll be forced to work long hours and work on broken code.

Level 3 managers are ideal, and they do exist. So if you can find a job working for them then you’re all set.

Level 2 managers are probably more common though, and you can get work/life balance working for them—if you set strong boundaries. Since they can recognize actual competence and skills, they won’t judge you during your interview based on how many hours you’re willing to work. You just need to convey your skill and value, and a reasonable amount of dedication to your job.

And once you’ve started work, if you can actually be productive (and if you work 40 hours/week you will be more productive!) they won’t care if you come in at 9 and leave at 5, because they’ll be happy with your work.

Unlike Level 3 managers, however, you need to be explicit about boundaries during the job interview, and even more so after you start. Elsewhere I wrote up some suggestions about how to convey your value, and how to say “no” to your boss.

Employment is a negotiated relationship

To put all this another way: employment is a negotiated relationship. Like it or not, you are negotiating from the moment you start interviewing, while you’re on the job, and until the day you leave.

You are trying to trade valuable work for money, learning opportunities, and whatever else your goals are (you can, for example, negotiate for a shorter workweek). In this case, we’re talking about negotiating for work/life balance:

1. Level 1 managers you can’t negotiate with, because what they want (long hours) directly conflicts with what you want.
2. Level 2 managers you can negotiate with, by giving them one of the things they want: valuable work.
3. Level 3 managers will give you what you want without your having to do anything, because they know it’s in the best interest of everyone.

Of course, even for Level 3 managers you will still need to negotiate other things, like a higher salary.

So how do you get a job with work/life balance? Focus on providing and demonstrating valuable long-term work, avoid bad companies, and make sure you set boundaries from the very start.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

Automated tests are immensely useful. Once you’ve started writing tests and seen their value, the idea of writing software without them becomes unimaginable.

But as with any technique, you need to understand its limitations. When it comes to automated testing—unit tests, BDD, end-to-end tests—it’s tempting to think that if your tests pass, your software is correct.

But tests don’t, tests can’t tell you that your software is correct. Let’s see why.

How to write correct software

To implement a feature or bugfix, you go through multiple stages; they might be compressed or elided, but they are always necessary:

1. Identification: Figure out what the problem is you’re trying to solve.
2. Solution: Come up with a solution.
3. Specification: Define a specification, the details of how the solution will be implemented.
4. Implementation: Implement the specification in code.

Your software might end up incorrect at any of these points:

1. You might identify the wrong problem.
2. You might choose the wrong solution.
3. You might create a specification that doesn’t match the solution.
4. You might write code that doesn’t match the specification.

Only human judgment can decide correctness

Automated tests are also a form of software, and are just as prone to error. The fact that your automated tests pass doesn’t tell you that your software is correct: you may still have identified the wrong problem, or chosen the wrong solution, and so on.

Even when it comes to ensuring your implementation matches your specification, tests can’t validate correctness on their own. Consider the following test:

def test_addition():
    assert add(2, 2) == 5

From the code’s perspective—the perspective of an automaton with no understanding—the correct answer of 4 is the one that will cause it to fail. But merely by reading that you can tell it’s wrong: you, the human, are key.

Correctness is something only a person can decide.

The value of testing: the process

While passing tests can’t prove correctness, the process of writing tests and making them pass can help make your software correct. That’s because writing the tests involves applying human judgment: What should this test assert? Does match the specification? Does this actually solve our problem?

When you go through the loop of writing tests, writing code, and checking if tests pass, you continuously apply your judgment: is the code wrong? is the test wrong? did I forget a requirement?

You write the test above, and then reread it, and then say “wait that’s wrong, 2 + 2 = 4”. You fix it, and then maybe you add to your one-off hardcoded tests some additional tests based on core arithmetic principles. Correctness comes from applying the process, not from the artifacts created by the process.

This may seem like pedantry: what does it matter whether the source of correctness is the tests themselves or the process of writing the tests? But it does matter. Understanding that human judgment is the key to correctness can keep you from thinking that passing tests are enough: you also need other forms of applied human judgment, like code review and manual testing.

(Formal methods augment human judgment with automated means… but that’s another discussion.)

The value of tests: stability

So if correctness comes from writing the tests, not the tests themselves, why do we keep the tests around?

Because tests ensure stability. once we judge the software is correct, the tests can keep the software from changing, and thus reduce the chances of its becoming incorrect. The tests are never enough, because the world can change even if the software isn’t, but stability has its value.

(Stability also has costs if you make the wrong abstraction layer stable…)

Tests are useful, but they’re not sufficient

To recap:

1. Write automated tests.
2. Run those tests.
3. Don’t mistake passing tests for correctness: you will likely need additional processes and techniques to achieve that.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

If you want to speak to me, 1-on-1, about anything, I want to be able to help. I am a busy person. I have commitments. But I will make the time to talk to you.

As a programmer looking for a job, you need to be on the lookout for badly managed companies. Whether it’s malicious exploitation or just plain incompetence, the less time you waste applying for these jobs, the better.

Some warning signs are subtle, but not all. One of the most blatant is a simple phrase: “must be willing to work under pressure.”

The distance between we and you

Let’s take a look at some quotes from real job postings. Can you spot the pattern?

• “Ability to work under pressure to meet sometimes aggressive deadlines.”
• “Thick skin, ability to overcome adversity, and keep a level head under pressure.”
• “Ability to work under pressure and meet tight deadlines.”
• “Willing to work under pressure” and “working extra hours if necessary.”

If you look at reviews for these companies, many of them mention long working hours, which is not surprising. But if you read carefully there’s more to it than that: it’s not just what they’re saying, it’s also how they’re saying it.

When it comes to talking about the company values, for example, it’s always in the first person: “we are risk-takers, we are thoughtful and careful, we turn lead into gold with a mere touch of our godlike fingers.” But when it comes to pressure it’s always in the second person or third person: it’s always something you need to deal with.

Who is responsible for the pressure? It’s a mysterious mystery of strange mystery.

But of course it’s not. Almost always it’s the employer who is creating the pressure. So let’s switch those job requirements to first person and see how it reads:

• “We set aggressive deadlines, and we will pressure you to meet them.”
• “We will say and do things you might find offensive, and we will pressure you.”
• “We set tight deadlines, and we will pressure you to meet them.”
• “We will pressure you, and we will make you work long hours.”

That sounds even worse, doesn’t it?

Dysfunctional organizations (that won’t admit it)

When phrased in the first person, all of these statements indicate a dysfunctional organization. They are doing things badly, and maybe also doing bad things.

But it’s not just that they’re dysfunctional: it’s also that they won’t admit it. Thus the use of the second or third person. It’s up to you to deal with this crap, cause they certainly aren’t going to try to fix things. Either:

1. Whoever wrote the job posting doesn’t realize they’re working for a dysfunctional organization.
2. Or, they don’t care.
3. Or, they can’t do anything about it.

None of these are good things. Any of them would be sufficient reason to avoid working for this organization.

Pressure is a choice

Now, I am not saying you shouldn’t take a job involving pressure. Consider the United States Digital Service, for example, which tries to fix and improve critical government software systems.

I’ve heard stories from former USDS employees, and yes, sometimes they do work under a lot of pressure: a critical system affecting thousands or tens of thousands of people goes down, and it has to come back up or else. But when the USDS tries to hire you, they’re upfront about what you’re getting in to, and why you should do it anyway.

They explain that if you join them your job will be “untangling, rewiring and redesigning critical government services.”. Notice how “untangling” admits that some things are a mess, but also indicates that your job will be to make things better, not just to passively endure a messed-up situation.

Truth in advertising

There’s no reason why companies couldn’t advertise in the some way. I fondly imagine that someone somewhere has written a job posting that goes like this:

“Our project planning is a mess. We need you, a lead developer/project manager who can make things ship on time. We know you’ll have to say ‘no’ sometimes, and we’re willing to live with that.”

Sadly, I’ve never actually encountered such an ad in the real world.

Instead you’ll be told “you must be able to work under pressure.” Which is just another way of saying that you should find some other, better jobs to apply to.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

We have more ways to manage dependencies in Python applications than ever. But how do they fare in production? Unfortunately this topic turned out to be quite polarizing and was at the center of a lot of heated debates. This is my attempt at an opinionated review through a DevOps lens.

(Thanks to Nelson Elhage and Saivickna Raveendran for their feedback on earlier drafts. All mistakes that remain are mine.)

When talking about garbage collection, the notion of "generational collection" comes up. The usual motivation given for generational garbage collection is that "most objects die young". Therefore, we put the objects that survive a collection cycle (and therefore have proven some resistance) in a separate generation that we scan less often.

This is an optimization if the probability of an object that has survived a cycle to be garbage by the time the next collection cycle has come around is lower than the probability of a newly allocated object to be garbage.

In a foundational paper Infant mortality and generational garbage collection, Dr. Baker laid out an argument deceptive in its simplicity.

Dr. Baker asks the question: "Can we model a process where most objects become garbage fast, but generational garbage collection would not improve things?". His answer is: of course. This is exactly the probability distribution of radioactive decay.

If we have a "fast decaying element", say with a half-life of one second, than 50% of the element's atoms decay in one second. However, keeping the atoms that "survived a generation" apart from newly created atoms is unhelpful: all remaining atoms decay with probability of 50%.

We can bring the probability for "young garbage" as high up as we want: a half-life of half a second, a quarter second, or a microsecond. However, that is not going to make generational garbage collection any better than a straightforward mark-and-sweep.

The Poisson distribution, which models radioactive decay, has the property that P(will die in one second) might be high, but P(will die in one second|survived an hour) is exactly the same: the past does not give us information about the future. This is called the "no memory property" of Poisson distribution.

When talking about generational garbage collection, and especially if we are making theoretical arguments about its helpfulness, we need to make arguments about the distribution, not about the averages. In other words, we need to make an argument that some kinds of objects hang around for a long time, while others tend to die quickly.

One way to model it is "objects are bimodal": if we model objects as belonging to a mix of two Gaussian distributions, one with a small average and one with a big average, then the motivation for generational collection is clear: if we tune it right, most objects that survive the first cycle belong to the other distribution, and will survive for a few more cycles.

To summarize: please choose your words carefully. "Young objects are more likely to die" is an accurate motivation, "Most objects die young" is not. This goes doubly if you do understand the subtlety: do not assume the people you are talking with have an accurate model of how garbage works.

As an aside, some languages decided that generational collection is more trouble than it is worth because the objects that "die young" go through a different allocation style. For example, Go has garbage collection, but it tries to allocate objects on the stack if it can guarantee at compile-time they do not "escape". Because of that, the "first generation" is collected at stack popping time.

CPython has generational garbage collection, but it also has a "zeroth generation" of sorts: when functions return, all local variables get a "decref": a decrease in reference count. Those for whom that results in a 0 reference counts, which is often quite a few, get collected immediately.

Most mornings I take Phoenix to school, as his school is two blocks away from work.

We take the subway to school, having about a half hour window to leave as the school has a half-hour play window before school really starts, which inevitably gets eaten up by collecting all the things, putting on all the clothes, picking the mode of transportation (no, not the stroller; please take the step so we can go fast), and getting out the door.

At the time we make it out, the subway is usually full of people, as are the cars, so we shuffle in and Phoenix searches for a seat, which is not available, but as long as he gets close enough to a pole and a person who looks like they’d be willing to give up a seat once they pay attention, he seems to get his way more often than not. And sometimes, the person next to them also offers up their seat to me. Which is when the fun begins.

Because, like any parent knows these days, as soon as you sit down next to each other, that one question will come:

“Papa, papa, papa… mag ik jouw telefoon?” (Can I have your phone? – Phoenix and I speak Dutch exclusively to each other. Well, I do to him.)

At which point, as a tired parent in the morning, you have a choice – let them have that Instrument of Brain Decay which even Silicon Valley parents don’t let their toddlers use, or push yourself to make every single subway ride an engaging and entertaining fun-filled program for the rest of eternity.

Or maybe… there is a middle way. Which is how, every morning, Phoenix and I engage in the same routine. I answer: “Natuurlijk mag jij mijn telefoon… als je éérst een verhaaltje vertelt.” (Of course you can have my phone – if you first tell me a story.)

Phoenix furrows his brows, and asks the only logical follow-up question there is – “Welk verhaaltje?” (Which story?)

And I say “Ik wil het verhaaltje horen van het jongetje en zijn vader die met de metro naar school gaan” (I want to hear the story of the little boy and his dad who take the subway to school.)

And he looks at me with big eyes and says, “Dat verhaaltje ken ik niet.” (I don’t know that story)

And I begin to tell the story:

“Er was eens… een jongetje en zijn vader.” (Once upon a time, there was a little boy and his father. Phoenix already knows the first three words of any story.)
“En op een dag… gingen dat jongetje en zijn vader met de metro naar school.” (And one day… the little boy and his father took the subway to school. The way he says “op een dag” whenever he pretends to read a story from a book is so endearing it is now part of our family tradition.)

“Maar toen de jongen en zijn vader op de metro stapten zat de metro vol met mensen. En het jongetje wou zitten, maar er was geen plaats. Tot er een vriendelijke mevrouw opstond en haar plaats gaf aan het jongetje, en het jongetje ging zitten. En toen stond de meneer naast de mevrouw ook recht en de papa ging naast het jongetje zitten.” (But when the little boy and his father got on the subway, it was full of people. And the little boy wanted to sit but there was no room. Until a friendly woman stood up and gave up her seat to the little boy, so the little boy sat down. And then the man next to the woman also stood up and his father sat down next to him.)

“En toen de jongen op de stoel zat, zei het jongetje, Papa papa papa papa papa papa papa…”(And when the boy sat down on the chair, he said Papa papa papa papa papa papa)

“Ja?, zei papa.” (Yes?, said papa.)

“Papa, mag ik jouw telefoon”? (Papa, can I have your phone?)

“Natuurlijk jongen….. als je éérst een verhaaltje vertelt.” (Of course son… if you first tell me a story.)

At which point, the story folds in on itself and recurses, and Phoenix’s eyes light up as he mouths parts of the sentences he already remembers, and joins me in telling the next level of recursion of the story.

I apologize in advance to all the closing parentheses left dangling like the terrible lisp programmer I’ve never given myself the chance to be, but making that train ride be phoneless every single time so far is worth it.

Do you love programming for its own sake, or do you do for the outcomes it allows? Depending on which describes you best you will face different problems in your career as a software developer.

Enthusiasts code out of love. If you’re an enthusiast you’d write software just for fun, but one day you discovered your hobby could also be your career, and now you get paid to do what you love.

Pragmatists may enjoy coding, but they do it for the outcomes. If you’re a pragmatist, you write software because it’s a good career, or for what it enables you to do and build.

There’s nothing inherently good or bad about either, and this is just a simplification. But understanding your own starting point can help you understand and avoid some of the problems you might encounter in your career.

In this post I will cover:

1. Why many companies prefer to hire enthusiasts.
2. The career problems facing enthusiasts, and how they can solve them.
3. The career problems facing pragmatists, and how they can solve them.

Why companies prefer hiring enthusiasts

Before we move on to specific career problems you might face, it’s worth looking at the bigger picture: the hiring and work environment.

Many companies prefer to hire enthusiast programmers: from the way they screen candidates to the way they advertise jobs, they try to hire people who care about the technology for its own sake. From an employer’s point of view, enthusiasts have a number of advantages:

1. In a rapidly changing environment, they’re more likely to keep up with the latest technologies. Even better, they’re more likely to do so in their free time, which means the company can spend less on training.
2. Since they’d write software for free, it’s easier to pay enthusiasts less money.
3. It’s also easier to get enthusiasts to work long hours.
4. Finally, since enthusiasts care more about the technical challenge than the goals of the product, they’re less likely to choose their work based on ethical or moral judgments.

But while many companies prefer enthusiasts, this isn’t always in the best interest of either side, as we’ll see next.

The career problems facing enthusiasts

So let’s say you’re an enthusiast. Here are some of the career problems you might face; not everyone will have all these problems, but it’s worth paying attention to see if you’re suffering from one or more of them.

1. Exploitation

As I alluded to above, companies like enthusiasts because they’re worse negotiators.

If you love what you do you’ll accept less money, you’ll work long hours, and you’ll ask less questions. This can cause you problems in the long run:

• Long hours can lead to burnout, in which case you might not enjoy coding at all, even in your spare time.
• Less money reduces your options outside of work.
• Finally, you really shouldn’t do work that’s immoral or unethical: there are plenty of fun problems that won’t make you feel guilty.

So even if you code for fun, you should still learn how to negotiate, if only out of self-defense.

2. Being less effective as an employee

Matt Dupree has an excellent writeup about why being an enthusiast can make you a worse worker; I don’t want to repeat his well-stated points here. Here are some additional ways in which enthusiasm can make you worse at your job:

• Shiny Object Syndrome: As an enthusiast it’s easy to choose a trendy technology or technique for your work because you want to play with it, not because it’s actually necessary in your situation. The most egregious example I’ve seen in recent years is microservices, where an organizational pattern designed for products with hundreds of programmers is being applied by teams with just a handful of developers.
• Writing code instead of solving problems: If you enjoy writing code for its own sake, it’s tempting to write more code just because it’s fun. Productivity as a programmer, however, comes from solving problems with as little work as needed.

3. Work vs. art

Finally, as an enthusiast you might face a constant sense of frustration. As an enthusiast, you want to write software for fun: solve interesting problems, write quality code, fine-tune your work until it’s beautiful.

But a work environment is all about outcomes, not about craft. And that means a constant pressure to compromise your artistic standards, a constant need to work on things that aren’t fun, and a constant need to finish things on time, rather than when you’re ready.

So unless you want to become a pragmatist, you might want to get back more time for yourself, time where you can write code however you like. You could, for example, negotiate a 3-day weekend.

The career problems facing pragmatists

Pragmatists face the opposite set of problems; again, not all pragmatists will have all of these problems, but you should keep your eye out to see if they’re affecting you.

1. It’s harder to find a job

Since many companies actively seek out enthusiasts, finding a job as a pragmatist can be somewhat harder. Here are some things you can do to work around this:

• Actively seek out companies that talk about work/life balance.
• When interviewing, amplify your enthusiasm for technology beyond what it actually is. After all, you will learn what you need to to get the results you want, right?
• Demonstrate the ways in which pragmatism actually makes you a more valuable employee.

2. You need to actively keep your skills up

Since you don’t care about technology for technology’s sake, it can be easy to let your skills get out of date, especially if you work for a company that doesn’t invest in training. To avoid this:

• Actively seek out tasks, projects, or new jobs that will force you to learn new technologies on the job, in depth.
• Spend an hour every week gathering a broad but superficial knowledge of new technologies.

3. Pressure to work long hours

Finally, you will often encounter pressure both from management and—indirectly—from enthusiast peers to work long hours. Just remember that working long hours is bad for you and your boss (even if they don’t realize it).

Programmer, know thyself

So are you an enthusiast or a pragmatist?

These are not exclusive categories, nor will they stay frozen with time—these days I’m more of a pragmatist, but I used to be more of an enthusiast—but there is a difference in attitudes. And that difference will lead to different choices, and different problems.

Once you know who you are, you can figure out what you want—and avoid the inevitable obstacles along the way.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

Chicken incubators are hot: eggs need heat to thrive. This was a different sort of incubator, a glass enclosure within a VC office. The VCs had the best views, but even we could look down ten stories and see the sun sparkling on the Charles River and reflecting off the buildings of downtown Boston.

It was summer when I joined the startup, but even so the incubator was freezing. The thermostat was skewed by a hot light sensor right below it, and the controls reset every night, so mornings were frigid. I took to wearing sweaters and fingerless gloves; the team at the other side of the incubator had figured out a way cover the AC vents with cardboard in a way that wasn’t visible to passersby.

But I didn’t have to suffer from the cold for very long. Soon after I joined the startup I unwittingly helped trigger our eviction from the rent-free Eden of the incubator to the harsher world outside.

The fall from grace

Most of the people who worked out of the incubator just used a laptop, or perhaps a monitor. But I like working with a standing desk, with a large Kinesis keyboard, and an external monitor on top.

My desk towered over everyone else: it was big and imposing and not very neat. Which is to say, the incubator started looking like a real office, not a room full of identical tables with a few Macbook Airs scattered hither and yon. And standing under the freezing air conditioner vent made my arms hurt, so I had to setup my desk in a way that was visible from the outside of the incubator.

And that view was too much for one of the partners in the VC firm. There were too many of us, we had too many cardboard boxes, my standing desk was just too big: it was time for us to leave the incubator.

The dream of workerless wealth

VCs take money, and (if all goes well) turn it into more money. But the actual reality of the work involved was too unpleasantly messy, too uncouth to be exposed to the sensibilities of wealthy clients.

We had to be banished out of sight, the ever-so-slightly grubby realities of office work hidden away, leaving only the clean cold dream of capital compounding through the genius of canny investors.

This dream—a dream of profit without workers—is the driving force behind many an investment fad:

• The dream in its purest form, Bitcoin and cryptocurrencies promise wealth pulled from thin air, spinning hay into gold without the involvement of any brutish Rumpelstiltskins.
• Driverless cars promise fleets of assets without those dirty, messy, expensive drivers; but until they come round, Uber and Lyft’s horde of drivers are safely kept at a distance as independent contractors with five star reviews.
• Artificial intelligence promises decision making without human involvement, an objective encoding of subjective prejudice that will never feel moral qualms.

And if you work for a VC-funded startup, this dream takes on a nightmarish tinge when it turns to consider you.

Unbanished—for now

The point here is not that VCs want to reduce effort: who wouldn’t want a more efficient world? The dream is not driven by visions of efficiency, it’s about status and aesthetics: doing actual work is ugly, and paying for work is offensive.

Of course, some level of work is always necessary and unavoidable. And so VC firms understand that the startups they fund must hire workers like me and you.

But the cold dream is always there, whispering in the background: these workers take equity, they take cash, they’re grubby. So when times are good hiring has to be done as quickly as possible, but when times are bad the layoffs come just as fast.

And when you are working, you need to work as many hours as humanly possible, not because it’s efficient—it isn't—but because paying for your time is offensive, and so you better damn well work hard. Your work may be necessary, but to the cold dream it’s a necessary—and ugly—evil.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

As my friend Thursday said in her excellent talk (sadly, not up as of this time) naming things is important. Avoiding in-jokes is, in general, a good idea.

It is with mixed feelings, therefore, that my pun-loving heart reacted to Chris's disclosure that the most common suggestion was to call the conference "Pythaluma". However, he decided to go with the straightforward legible name, "North Bay Python".

North of the city by the bay, lies the quiet yet chic city of Petaluma, where North Bay Python takes place. In a gold-rush-city turned sleepy wine country, a historical cinema turned live show venu hosted Python enthusiasts in a single-track conference.

Mariatta opened the conference with her gut-wrenching talk about being a core Python developer. "Open source sustainability" might be abstract words, but it is easy to forget that for a language that's somewhere between the first and fifth most important (depending on a metric) there are less than a hundred people supporting its core -- and if they stop, the world breaks.

R0ml opened the second day of the conference talking about how:

• Servers are unethical.
• Python is the new COBOL.
• I put a lot of pressure on him before his talk.

Talks are still being uploaded to the YouTube channel, and I have already had our engineering team at work watch Hayley's post-mortem of Jurassic Park.

If you missed all of it, I have two pieces of advice:

• Watch the videos. Maybe even mine.
• Sign up to the mailing list so you will not miss next year's.

If you went there, I hope you told me hi. Either way, please say hi next year!

You’ve got to meet your deadlines, you’ve got to fix the bug, you’ve got to ship the product.

But you’ve also got to think about the future: every bug you introduce now will have to be fixed later, using up even more time. And all those deprecated APIs, out-of-date dependencies, and old ways of doing things really shouldn’t be there.

So when do you clean up your code?

Do you do it now?

Later?

Never?

In this article I’ll go over a set of heuristics that will help you decide when to apply three kinds of fixes:

1. Updating dependencies that are out-of-date and usages of deprecated APIs.
2. Refactoring to fix bad abstractions.
3. Miscellaneous Cleanups of anything else, from coding standard violations to awkward idioms.

Heuristics by situation

Prototyping

Before you start building something in earnest, you might start with a prototype (or what Extreme Programming calls a “spike”). You’re not going to keep this code, you’re just exploring the problem and solution space to see what you can learn.

Given you’re going to throw away this code, there’s not much point in Updating or Miscellaneous Cleanups. And if you’re just trying to understand an existing API or technical issue, you won’t be doing much Refactoring wither.

On the other hand, if your goal with prototyping is to find the right abstraction, you will be doing lots of Refactoring.

1. Updating: never.
2. Refactoring: now if you’re trying to prototype an API or abstraction, otherwise never.
3. Miscellaneous Cleanups: never.

A new project

When you’re starting a completely new project, the decisions you make will have a strong impact on the maintenance code going forward.

This is a great opportunity to start with the latest (working) dependencies, situation-specific best practices and maintainable code, and the best abstractions you can come up with. You probably won’t get them completely right, but it’s usually worth spending the time to try to get it as close as possible.

1. Updating: now.
2. Refactoring: now.
3. Miscellaneous Cleanups: now.

An emergency bugfix

You need to get a bug fix to users ASAP. While you might see problems along the way, but unless they’re relevant to this particular bug fix, it’s best to put them off until later.

Sometimes that might mean fixing the bug twice: once in a quick hacky way, and a second time after you’ve done the necessary cleanups.

1. Updating: later.
2. Refactoring: later.
3. Miscellaneous Cleanups: later.

New feature or non-urgent bugfix

When you have a project in active development and you’re doing ongoing work, whether features or bug fixes, you have a great opportunity to incrementally clean up your code.

You don’t need to fix everything every time you touch the code. Instead, an ongoing cleanup of code you’re already touching will cumulatively keep your codebase in good shape. See Ron Jefferies’ excellent article for details.

1. Updating: now, for code you’re touching.
2. Refactoring: now, for code you’re touching.
3. Miscellaneous Cleanups: now, for code you’re touching.

A project in maintenance mode

Eventually your project will be finished: not much new development is done, and mostly it just gets slightly tweaked every few months when something breaks or a drop-down menu needs an extra option.

Your goal at this point is to do the minimum work necessary to keep the project going. Refactoring and Miscellaneous Cleanups aren’t necessary, but Updates might be—dependencies can stop working, or need security updates. And jumping your dependencies 5 years ahead is often much harder than incrementally doing 5 dependency updates at yearly intervals.

So whenever you have to do fix a bug, you should update the dependencies—ideally to Long Term Support releases to reduce the need for API usage updates.

1. Updating: now, ideally to Long Term Support releases.
2. Refactoring: never.
3. Miscellaneous Cleanups: never.

Balancing present and future

Software projects tend to ongoing processes, not one-off efforts. A cleanup now might save you time later—but if you have a deadline to meet now, it might be better to put it off even at the cost of slightly more work later on.

So takes this article only a starting point: as with any heuristic, there will be exceptions to the rule, and you need to be guided by your situation and your goals.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

How to ensure that your tests run code that you think they are running, and how to measure your coverage over multiple tox runs (in parallel!).

Deadlines are hard to navigate.

On the one hand you risk crashing into the rocks of late delivery, and on the other you risk drowning in a whirlpool of broken software and technical debt.

And if you end up working long hours—if your only solution is crunch time—you risk both burnout and technical debt at the same time. Metaphorically, you risk drowning in a whirlpool full of fire-breathing rocks.

Given too much work and not enough time, you need to say “no” to your boss and negotiate a better set of deliverables—but what exactly should you be aiming for?

• You could argue for maintainable, well-tested code, and deadlines be damned. But what if the deadline is important?
• Or you could argue for meeting the deadline no matter what, even if that means shipping untested or buggy code. But doesn’t the code need to work?

This dilemma is a false dichotomy. Quality is situation-specific and feature-specific, and rote answers aren’t enough to decide on an implementation strategy.

The real answer is to prioritize the work that really matters in your particular situation, and jettison the rest until after the deadline. And that means saying “no”: saying no to your boss, saying no to your customer, and saying no to yourself.

No, all the code can’t be perfect (but this part needs to be rock solid).

No, that feature isn’t important for addressing our goals.

No, we can’t just add one small thing. But yes, we will do what really matters.

Let’s consider two examples: the same task, but very different goals and implementations.

Deadline #1: Raise money or lose your job

I once worked at a startup that was starting to run out of money: our existing business was not working. Luckily, the co-founders had come up with a plan. We would pivot to a trendy new area—Docker was just gaining traction—where we could build something no one else could do at the time.

Now, this meant were going to be building a distributed system, a notoriously difficult and complex task. And we had a deadline we had to meet: we were going to do a press campaign for our initial release, and that requires a few weeks of lead time. And of course on a broader level we needed to make enough of an impression that we could get funding before our current money ran out.

How do you build a complex, sophisticated piece of software with a short deadline? You start with your goals.

Start with your goals

Our goal was to demonstrate the key feature that only our software could do. We decided to do that by having users walk through a tutorial that demonstrated our value proposition. If the user was impressed with our tutorial then we’d succeeded; we explicitly told users that the software was not yet usable in the real world.

Based on this operational goal we were able to make a whole slew of simplifications:

1. A production system would need to support parallel operation, but our tutorial only needed to be used by a single user. So we implemented the distributed system by having a CLI that SSHed into a machine and ran another CLI.
2. A production system would need to handle errors, but our tutorial could run in a controlled environment. We created a Vagrant config that started two virtual machines, and didn’t bother writing error handling for lost connections, inaccessible machines, and so on.
3. A production system would need to be upgradeable and maintainable, but our tutorial would only be run once. So we didn’t bother writing unit tests for most of it, and focused instead on manually running through the tutorial.

Now, you might be thinking “but you’re choosing to abandon quality”. But again, none of the things we dropped were relevant to our goal at that time. Spending time on “best practices” that aren’t relevant to your particular situation is a waste of time.

We were very clear in all our documentation and marketing efforts that this was a demonstration only, and that we would be following up later with a production-ready release.

Prioritize features by goals

Even with these simplifications, we ended up dropping features to meet the deadline. How did we decide which futures to drop?

We started by implementing the minimal features needed to demonstrate our core value, and so when we ran out of time we dropped the remaining, less critical features. We stopped coding before the drop date (a week or a few days, I believe), and focused just on testing and polishing our documentation.

Dropping features was quite alright: the idea was good enough, the tutorial was compelling enough, and our VP of Marketing was skilled enough, that we were able to raise a $12 million Series A based off that unscalable, unmaintainable piece of software. And after the initial release and publicity push we had time to implement those later features to keep up our momentum.

Deadline #2: Production-ready software

Once we had VC funding we rebuilt the product with the same set of features, but a very different goal: a production-ready product. That meant we needed a good architecture, an installer, error handling, good test coverage, and so on. It took much longer, and required a much bigger team, but that was OK: we had a different goal, and enough funding to allow for a longer deadline (again, based on publicity needs).

Even so, we made sure to choose and prioritize our work based on our goal: getting users and customers for our product. Our initial prototype had involved a peer-to-peer storage transfer mechanism, and making that production ready would have been a large R&D exercise. So in the short term we focused on cloud storage, a much simpler problem.

And we made sure to drop less important features as deadlines approached. We certainly didn’t do a perfect job, e.g. we dropped one feature that was half-implemented. We would have done better not starting it at all, since it was less important. But, we succeeded: the code was maintainable, people started using it, and we didn’t have to rely on crunch time to deliver.

Beyond universal solutions

There is no universal solution that will work everywhere, no easy answers. All you can do is ask “why”: why are we doing this, and why does this matter?

Once you know your goals, you can try and prioritize—and negotiate for—a solution that achieves your goals, meets the deadline, and doesn’t involve long hours:

1. Drop features that don’t further your goals, and start with the most important features, in case you run out of time for the rest.
2. Write high-quality code in the places where it matters, and drop “quality” where it doesn’t (what Havoc Pennington calls “professional corner-cutting”, emphasis on professional.)
3. And if you still have too much work, it’s time to have a discussion with your boss or customer about what tradeoffs they actually want.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

These are a few quick notes to self, rather than a cogent thesis. I want to get this out while it’s still fresh, and I want to lower my own mental barrier to publishing here.

I’ve been thinking about test coverage recently, inspired by conversations that followed DRMacIver’s recent post.

Here’s my current working hypothesis:

• every new project should have 100% test coverage
• every existing project should have a ratchet that enforces increasing coverage
• “100% coverage” means that every line is either:
  • covered by the test suite
  • or has some markup in code saying that it is explicitly not covered, and why that’s the case
• these should be enforced in CI

The justification is that “the test of all knowledge is experiment” [0]. While we should absolutely make our code easy to reason about, and prove as much as we can about it, we need to check what it does against actual reality.

Simple testing really can prevent most critical failures. It’s OK to not test some part of your code, but that should be a conscious, local, recorded decision. You have to explicitly opt out of test coverage. The tooling should create a moment where you either write a test, or you turn around and say “hold my beer”.

Switching to this for an existing project can be prohibitively expensive, though, so a ratchet is a good idea. The ratchet should be “lines of uncovered code”, and that should only be allowed to go down. Don’t ratchet on percentages, as that will let people add new lines of uncovered code.

Naturally, all of this has to be enforced in CI. No one is going to remember to run the coverage tool, and no one is going to remember to check for it during code review. Also, it’s almost always easier to get negative feedback from a robot than a human.

I tagged this post with Haskell, because I think all of this is theoretically possible to achieve on a Haskell project, but requires way too much tooling to set up.

• hpc is great, but it is not particularly user friendly.
• Existing code coverage SaaS services don’t support expression-level coverage.
• hpc has mechanisms for excluding code from coverage, but it’s not by marking up your code
• hpc has some theoretically correct but pragmatically unfortunate defaults, e.g. it’ll report partial coverage for an otherwise guard, because it’s never run through when otherwise is False
• There are no good ratchet tools

As a bit of an experiment, I set up a test coverage ratchet with graphql-api. I wanted both to test out my new enthusiasm for aiming for 100% coverage, and I wanted to make it easier to review PRs.

The ratchet script is some ad hoc Python, but it’s working. External contributors are actually writing tests, because the computer tells them to do so. I need to think less hard about PRs, because I can look at the tests to see what they actually do. And we are slowly improving our test coverage.

I want to build on this tooling to provide something genuinely good, but I honestly don’t have the budget for it at present. I hope to at least write a good README or user guide that illustrates what I’m aiming for. Don’t hold your breath.

You’ve been working as a programmer for a few years, you’ve been promoted once or twice, and now you’re wondering what’s next. The path until this point was straightforward: you learned how to work on your own, and then you get promoted to Senior Software Engineer or some equivalent job title.

But now there’s no clear path ahead.

Do you become a manager and stop coding?

Do you just learn new technologies, or is that not enough?

What should you be aiming for?

In this post I’d like to present an alternative career progression, an alternative that will give you more autonomy, and more bargaining power. And unlike becoming a manager, it will still allow you to write code.

From coding to solving problems

In the end, your job as a programmer is solving problems, not writing code. Solving problems requires:

1. Finding and identifying the problem.
2. Coming up with a solution.
3. Implementing the solution.

Each of these can be thought of a skill-tree: a set of related skills that can be developed separately and in parallel. In practice, however, you’ll often start in reverse order with the third skill tree, and add the others on one by one as you become more experienced.

Randall Koutnik describes these as job titles of a sort, a career progression: Implementers, Solvers, and Finders.

As an Implementer, you’re an inexperienced programmer, and your tasks are defined by someone else: you just implement small, well-specified chunks of code.

Let’s imagine you work for a company building a website for animal owners. You go to work and get handed a task: “Add a drop-down menu over here listing all iguana diseases, which you can get from the IGUANA_DISEASE table. Selecting a menu item should redirect you the appropriate page.”

You don’t know why a user is going to be listing iguana diseases, and you don’t have to spend too much time figuring out how to implement it. You just do what you’re told.

As you become more experienced, you become a Solver: are able to come up with solutions to less well-defined problems.

You get handed a problem: “We need to add a section to the website where pet owners can figure out if their pet is sick.” You figure out what data you have and which APIs you can use, you come up with a UI together with the designer, and then you create an implementation plan. Then you start coding.

Eventually you become a Finder: you begin identifying problems on your own and figuring out their underlying causes.

You go talk to your manager about the iguanas: almost no one owns iguanas, why are they being given equal space on the screen as cats and dogs? Not to mention that writing iguana-specific code seems like a waste of time, shouldn’t you be writing generic code that will work for all animals?

After some discussion you figure out that the website architecture, business logic, and design are going to have to be redone so that you don’t have to write new code every time a new animal is added. If you come up with the right architecture, adding a new animal will take just an hour’s work, so the company can serve many niche animal markets at low cost. Designing and implementing the solution will likely be enough work that you’re going to have to work with the whole team to do it.

The benefits of being a Finder

Many programmers end up as Solvers and don’t quite know what to do next. If management isn’t your thing, becoming a Finder is a great next step, for two reasons: autonomy and productivity.

Koutnik’s main point is that each of these three stages gives you more autonomy. As an Implementer you have very little autonomy, as a Solver you have more, and as a Finder you have lots: you’re given a pile of vague goals and constraints and it’s up to you to figure out what to do. And this can be a lot of fun.

But there’s another benefit: as you move from Implementer to Solver to Finder you become more productive, because you’re doing less unnecessary work.

• If you’re just implementing a solution someone else specified, then you might be stuck with an inefficient solution.
• If you’re just coming up with a solution and taking the problem statement at face value, then you might end up solving the wrong problem, when there’s another more fundamental problem that’s causing all the trouble.

The better you are at diagnosing and identifying underlying problems, coming up with solutions, and working with others, the less unnecessary work you’ll do, and the more productive you’ll be.

Leveraging your productivity

If you’re a Finder you’re vastly more productive, which makes you a far more valuable employee. You’re the person who finds the expensive problems, who identifies the roadblocks no one knew where there, who discovers what your customers really wanted.

And that means you have far more negotiating leverage:

• You can more easily negotiate a raise.
• You can find better jobs, even with a technology you don’t know.
• You can even negotiate a 3-day weekend.

So if you want to keep coding, and you still want to progress in your career, start looking for problems. If you pay attention, you’ll find them everywhere.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

(Thanks to Brian for his feedback. All mistakes and omissions that remain are mine.)

Some commands have a --dry-run option, which simulates running the command but without taking effect. Sometimes the option exists for speed reasons: just pretending to do something is faster than doing it. However, more often this is because doing it can cause big, possibly detrimental, effects, and it is nice to be able to see what would happen before running the script.

For example, ansible-playbook has the --check option, which will not actually have any effect: it will just report what ansible would have done. This is useful when editing a playbook or changing the configuration.

However, this is the worst possible default. If we have already decided that our command can cause much harm, and one way to mitigate the harm is to run it in a "dry run" mode and have a human check that this makes sense, why is "cause damage" the default?

As someone in SRE/DevOps jobs, many of the utilities I run can cause great harm without care. They are built to destroy whole environments in one go, or to upgrade several services, or to clean out unneeded data. Running it against the wrong database, or against the wrong environment, can wreak all kinds of havoc: from disabling a whole team for a day to actual financial harm to the company.

For this reason, the default of every tool I write is to run in dry run mode, and when wanting to actually have effect, explicitly specify --no-dry-run. This means that my finger accidentally slipping on the enter key just causes something to appear on my screen. After I am satisfied with the command, I up-arrow and add --no-dry-run to the end.

I now do it as a matter of course, even for cases where the stakes are lower. For example, the utility that publishes this blog has a --no-dry-run that publishes the blog. When run without arguments, it renders the blog locally so I can check it for errors.

So I really have no excuses... When I write a tool for serious production system, I always implement a --no-dry-run option, and have dry runs by default. What about you?

(Thanks to Brian for his feedback. All mistakes and omissions that remain are mine.)

Some commands have a --dry-run option, which simulates running the command but without taking effect. Sometimes the option exists for speed reasons: just pretending to do something is faster than doing it. However, more often this is because doing it can cause big, possibly detrimental, effects, and it is nice to be able to see what would happen before running the script.

For example, ansible-playbook has the --check option, which will not actually have any effect: it will just report what ansible would have done. This is useful when editing a playbook or changing the configuration.

However, this is the worst possible default. If we have already decided that our command can cause much harm, and one way to mitigate the harm is to run it in a "dry run" mode and have a human check that this makes sense, why is "cause damage" the default?

As someone in SRE/DevOps jobs, many of the utilities I run can cause great harm without care. They are built to destroy whole environments in one go, or to upgrade several services, or to clean out unneeded data. Running it against the wrong database, or against the wrong environment, can wreak all kinds of havoc: from disabling a whole team for a day to actual financial harm to the company.

For this reason, the default of every tool I write is to run in dry run mode, and when wanting to actually have effect, explicitly specify --no-dry-run. This means that my finger accidentally slipping on the enter key just causes something to appear on my screen. After I am satisfied with the command, I up-arrow and add --no-dry-run to the end.

I now do it as a matter of course, even for cases where the stakes are lower. For example, the utility that publishes this blog has a --no-dry-run that publishes the blog. When run without arguments, it renders the blog locally so I can check it for errors.

So I really have no excuses... When I write a tool for serious production system, I always implement a --no-dry-run option, and have dry runs by default. What about you?

You’re hard at work writing code: you need to ship a feature on time, or release a whole new product, and you’re pouring all your time and energy into it, your heart and your soul. And then, an uninvited and dangerous question insinuates itself into your consciousness.

If you succeed, if you ship your code, if you release your product, will you be happy? Will all your time and effort be worth it?

And you realize the answer is “no”. And suddenly your work is worthless, your goals are meaningless. You just can’t force yourself to work on something that doesn’t matter.

Why bother? Why work at all?

This is not a new experience. Almost 200 years ago, John Stuart Mill went through this crisis. And being a highly verbose 19th century philosopher, he also wrote a highly detailed explanation how he managed to overcome what we would call depression or burnout.

And this explanation is useful not just to his 19th century peers, but to us programmers as well.

“Intellectual enjoyments above all”

At the core of Mill’s argument is the idea that rational thought, “analysis” he calls it, is corrosive: “a perpetual worm at the root both of the passions and of the virtues”. He never rejected rational thought, but he concluded that on its own it was insufficient, and potentially dangerous.

Mill’s education had, from an early age, focused him solely on rational analysis. As a young child Mill was taught by his father to understand—not just memorize—Greek, arithmetic, history, mathematics, political economy, far more than even many well-educated adults learned at the time. And since he was taught at home without outside influences, he internalized his father’s ideas prizing intellect over emotions.

In particular, Mill’s father “never varied in rating intellectual enjoyments above all others… For passionate emotions of all sorts, and for everything which has been said or written in exaltation of them, he professed the greatest contempt.” Thus Mill learned to prize rational thought and analysis over other feelings, as many programmers do—until he discovered the cost of focusing on those alone.

“The dissolving influence of analysis”

One day, things went wrong:

I was in a dull state of nerves, such as everybody is occasionally liable to; unsusceptible to enjoyment or pleasurable excitement; one of those moods when what is pleasure at other times, becomes insipid or indifferent…

In this frame of mind it occurred to me to put the question directly to myself: “Suppose that all your objects in life were realized; that all the changes in institutions and opinions which you are looking forward to, could be completely effected at this very instant: would this be a great joy and happiness to you?” And an irrepressible self-consciousness distinctly answered, “No!”

From this point on Mill suffered from depression, for months on end. And being of an analytic frame of mind, he was able to intellectually diagnose his problem.

On the one hand, rational logical thought is immensely useful in understanding the world: “it enables us mentally to separate ideas which have only casually clung together”. But this ability to analyze also has its costs, since “the habit of analysis has a tendency to wear away the feelings”. In particular, analysis “fearfully undermine all desires, and all pleasures”.

Why should this make you happy? You try to analyze it logically, and eventually conclude there is no reason it should—and now you’re no longer happy.

“Find happiness by the way”

Eventually an emotional, touching scene in a book he was reading nudged Mill out of his misery, and when he fully recovered he changed his approach to life in order to prevent a recurrence.

Mill’s first conclusion was that happiness is a side-effect, not a goal you can achieve directly, nor verify directly by rational self-interrogation. Whenever you ask yourself “can I prove that I’m happy?” the self-consciousness involved will make the answer be “no”. Instead of choosing happiness as your goal, you need to focus on some other thing you care about:

Those only are happy (I thought) who have their minds fixed on some object other than their own happiness; on the happiness of others, on the improvement of mankind, even on some art or pursuit, followed not as a means, but as itself an ideal end. Aiming thus at something else, they find happiness by the way.

It’s worth noticing that Mill is suggesting focusing on something you actually care about. If you’re spending your time working on something that meaningless to you, you will probably have a harder time of it.

“The internal culture of the individual”

Mill’s second conclusion was that logical thought and analysis are not enough on their own. He still believed in the value of “intellectual culture”, but he also aimed to become a more balanced person by “the cultivation of the feelings”. And in particular, he learned the value of “poetry and art as instruments of human culture”.

For example, Mill discovered Wordsworth’s poetry:

These poems addressed themselves powerfully to one of the strongest of my pleasurable susceptibilities, the love of rural objects and natural scenery; to which I had been indebted not only for much of the pleasure of my life, but quite recently for relief from one of my longest relapses into depression….

What made Wordsworth’s poems a medicine for my state of mind, was that they expressed, not mere outward beauty, but states of feeling, and of thought coloured by feeling, under the excitement of beauty. They seemed to be the very culture of the feelings, which I was in quest of. In them I seemed to draw from a Source of inward joy, of sympathetic and imaginative pleasure, which could be shared in by all human beings…

Both nature and art cultivate the feelings, an additional and distinct way of being human beyond logical analysis:

The intensest feeling of the beauty of a cloud lighted by the setting sun, is no hindrance to my knowing that the cloud is vapour of water, subject to all the laws of vapours in a state of suspension…

The practice of happiness

Mill’s advice is not a universal panacea; among other flaws, it starts from a position of immense privilege. But I do think Mill hits on some important points about what it means to be human.

If you wish to put it into practice, here is Mill’s advice, insofar as I can summarize it (I encourage you to go and read his Autobiography on your own):

1. Aim in your work not for happiness, but for a goal you care about: improving the world, or even just applying and honing a skill you value.
2. Your work—and the rational thought it entails—will not suffice to make you happy; rational thought on its own will undermine your feelings.
3. You should therefore also cultivate your feelings: through nature, and through art.

There’s always too much work to do: too many features to implement, too many bugs to fix—and working evenings and weekends won’t help.

The real solution is working fewer hours. Learn how you can get a 3-day weekend.

I caught Toshio Kuratomi's post about asyncio initialization patterns (or anti-patterns) on Planet Python. This is something I've dealt with a lot over the years using Twisted (one of the sources of inspiration for the asyncio developers).

To recap, Toshio wondered about a pattern involving asynchronous initialization of an instance. He wondered whether it was a good idea to start this work in __init__ and then explicitly wait for it in other methods of the class before performing the distinctive operations required by those other methods. Using asyncio (and using Toshio's example with some omissions for simplicity) this looks something like:

class Microblog:
    def __init__(self, ...):
        loop = asyncio.get_event_loop()
        self.init_future = loop.run_in_executor(None, self._reading_init)

    def _reading_init(self):
        # ... do some initialization work,
        # presumably expensive or otherwise long-running ...

   @asyncio.coroutine
    def sync_latest(self):
        # Don't do anything until initialization is done
        yield from self.init_future
        # ... do some work that depends on that initialization ...

It's quite possible to do something similar to this when using Twisted. It only looks a little bit difference:

class Microblog:
    def __init__(self, ...):
        self.init_deferred = deferToThread(self._reading_init)

    def _reading_init(self):
        # ... do some initialization work,
        # presumably expensive or otherwise long-running ...

   @inlineCallbacks
    def sync_latest(self):
        # Don't do anything until initialization is done
        yield self.init_deferred
        # ... do some work that depends on that initialization ...

Despite the differing names, these two pieces of code basical do the same thing:

• run _reading_init in a thread from a thread pool
• whenever sync_latest is called, first suspend its execution until the thread running _reading_init has finished running it

Maintenance costs

One thing this pattern gives you is an incompletely initialized object. If you write m = Microblog() then m refers to an object that's not actually ready to perform all of the operations it supposedly can perform. It's either up to the implementation or the caller to make sure to wait until it is ready. Toshio suggests that each method should do this implicitly (by starting with yield self.init_deferred or the equivalent). This is definitely better than forcing each call-site of a Microblog method to explicitly wait for this event before actually calling the method.

Still, this is a maintenance burden that's going to get old quickly. If you want full test coverage, it means you now need twice as many unit tests (one for the case where method is called before initialization is complete and another for the case where the method is called after this has happened). At least. Toshio's _reading_init method actually modifies attributes of self which means there are potentially many more than just two possible cases. Even if you're not particularly interested in having full automated test coverage (... for some reason ...), you still have to remember to add this yield statement to the beginning of all of Microblog's methods. It's not exactly a ton of work but it's one more thing to remember any time you maintain this code. And this is the kind of mistake where making a mistake creates a race condition that you might not immediately notice - which means you may ship the broken code to clients and you get to discover the problem when they start complaining about it.

Diminished flexibility

Another thing this pattern gives you is an object that does things as soon as you create it. Have you ever had a class with a __init__ method that raised an exception as a result of a failing interaction with some other part of the system? Perhaps it did file I/O and got a permission denied error or perhaps it was a socket doing blocking I/O on a network that was clogged and unresponsive. Among other problems, these cases are often difficult to report well because you don't have an object to blame the problem on yet. The asynchronous version is perhaps even worse since a failure in this asynchronous initialization doesn't actually prevent you from getting the instance - it's just another way you can end up with an incompletely initialized object (this time, one that is never going to be completely initialized and use of which is unsafe in difficult to reason-about ways).

Another related problem is that it removes one of your options for controlling the behavior of instances of that class. It's great to be able to control everything a class does just by the values passed in to __init__ but most programmers have probably come across a case where behavior is controlled via an attribute instead. If __init__ starts an operation then instantiating code doesn't have a chance to change the values of any attributes first (except, perhaps, by resorting to setting them on the class - which has global consequences and is generally icky).

Loss of control

A third consequence of this pattern is that instances of classes which employ it are inevitably doing something. It may be that you don't always want the instance to do something. It's certainly fine for a Microblog instance to create a SQLite3 database and initialize a cache directory if the program I'm writing which uses it is actually intent on hosting a blog. It's most likely the case that other useful things can be done with a Microblog instance, though. Toshio's own example includes a post method which doesn't use the SQLite3 database or the cache directory. His code correctly doesn't wait for init_future at the beginning of his post method - but this should leave the reader wondering why we need to create a SQLite3 database if all we want to do is post new entries.

Using this pattern, the SQLite3 database is always created - whether we want to use it or not. There are other reasons you might want a Microblog instance that hasn't initialized a bunch of on-disk state too - one of the most common is unit testing (yes, I said "unit testing" twice in one post!). A very convenient thing for a lot of unit tests, both of Microblog itself and of code that uses Microblog, is to compare instances of the class. How do you know you got a Microblog instance that is configured to use the right cache directory or database type? You most likely want to make some comparisons against it. The ideal way to do this is to be able to instantiate a Microblog instance in your test suite and uses its == implementation to compare it against an object given back by some API you've implemented. If creating a Microblog instance always goes off and creates a SQLite3 database then at the very least your test suite is going to be doing a lot of unnecessary work (making it slow) and at worst perhaps the two instances will fight with each other over the same SQLite3 database file (which they must share since they're meant to be instances representing the same state). Another way to look at this is that inextricably embedding the database connection logic into your __init__ method has taken control away from the user. Perhaps they have their own database connection setup logic. Perhaps they want to re-use connections or pass in a fake for testing. Saving a reference to that object on the instance for later use is a separate operation from creating the connection itself. They shouldn't be bound together in __init__ where you have to take them both or give up on using Microblog.

Alternatives

You might notice that these three observations I've made all sound a bit negative. You might conclude that I think this is an antipattern to be avoided. If so, feel free to give yourself a pat on the back at this point.

But if this is an antipattern, is there a pattern to use instead? I think so. I'll try to explain it.

The general idea behind the pattern I'm going to suggest comes in two parts. The first part is that your object should primarily be about representing state and your __init__ method should be about accepting that state from the outside world and storing it away on the instance being initialized for later use. It should always represent complete, internally consistent state - not partial state as asynchronous initialization implies. This means your __init__ methods should mostly look like this:

class Microblog(object):
    def __init__(self, cache_dir, database_connection):
        self.cache_dir = cache_dir
        self.database_connection = database_connection

If you think that looks boring - yes, it does. Boring is a good thing here. Anything exciting your __init__ method does is probably going to be the cause of someone's bad day sooner or later. If you think it looks tedious - yes, it does. Consider using Hynek Schlawack's excellent attrs package (full disclosure - I contributed some ideas to attrs' design and Hynek ocassionally says nice things about me (I don't know if he means them, I just know he says them)).

The second part of the idea an acknowledgement that asynchronous initialization is a reality of programming with asynchronous tools. Fortunately __init__ isn't the only place to put code. Asynchronous factory functions are a great way to wrap up the asynchronous work sometimes necessary before an object can be fully and consistently initialized. Put another way:

class Microblog(object):
    # ... __init__ as above ...

    @classmethod
    @asyncio.coroutine
    def from_database(cls, cache_dir, database_path):
        # ... or make it a free function, not a classmethod, if you prefer
        loop = asyncio.get_event_loop()
        database_connection = yield from loop.run_in_executor(None, cls._reading_init)
        return cls(cache_dir, database_connection)

Notice that the setup work for a Microblog instance is still asynchronous but initialization of the Microblog instance is not. There is never a time when a Microblog instance is hanging around partially ready for action. There is setup work and then there is a complete, usable Microblog.

This addresses the three observations I made above:

• Methods of Microblog never need to concern themselves with worries about whether the instance has been completely initialized yet or not.
• Nothing happens in Microblog.__init__. If Microblog has some methods which depend on instance attributes, any of those attributes can be set after __init__ is done and before those other methods are called. If the from_database constructor proves insufficiently flexible, it's easy to introduce a new constructor that accounts for the new requirements (named constructors mean never having to overload __init__ for different competing purposes again).
• It's easy to treat a Microblog instance as an inert lump of state. Simply instantiating one (using Microblog(...) has no side-effects. The special extra operations required if one wants the more convenient constructor are still available - but elsewhere, where they won't get in the way of unit tests and unplanned-for uses.

I hope these points have made a strong case for one of these approaches being an anti-pattern to avoid (in Twisted, in asyncio, or in any other asynchronous programming context) and for the other as being a useful pattern to provide both convenient, expressive constructors while at the same time making object initializers unsurprising and maximizing their usefulness.

You’re six months into a project when you realize a tiny, simple assumption you made at the start was completely wrong. And now you need to fix the problem while keeping the existing system running—with far more effort than it would’ve taken if you’d just gotten it right in the first place.

Today I’d like to tell you about one common mistake, a single word that will cause you endless trouble. I am speaking, of course, about “users”.

There are two basic problems with this word:

1. “User” is almost never a good description of your requirements.
2. “User” encourages a fundamental security design flaw.

The concept “user” is dangerously vague, and you will almost always be better off using more accurate terminology.

You don’t have users

To begin with, no software system actually has “users”. At first glance “user” is a fine description, but once you look a little closer you realize that your business logic actually has more complexity than that.

We’ll consider three examples, starting with an extreme case.

Airline reservation systems don’t have “users”

I once worked on the access control logic for an airline reservation system. Here’s a very partial list of the requirements:

• Travelers can view their booking through the website if they have the PNR locator.
• Purchasers can modify the booking through the website if they have the last 4 digits of the credit card number.
• Travel agents can see and modify bookings made through their agency.
• Airline check-in agents can see and modify bookings based on their role and airport, given identifying information from the traveler.

And so on and so forth. Some the basic concepts that map to humans are “Traveler”, “Agent” (the website might also be an agent), and “Purchaser”. The concept of “user” simply wasn’t useful, and we didn’t use the word at all—in many requests, for example, we had to include credentials for both the Traveler and the Agent.

Unix doesn’t have “users”

Let’s take a look at a very different case. Unix (these days known as POSIX) has users: users can log-in and run code. That seems fine, right? But let’s take a closer look.

If we actually go through all the things we call users, we have:

• Human beings who log in via a terminal or graphical UI.
• System services (like mail or web servers) who also run as “users”, e.g. nginx might run as the httpd user.
• On servers, there are often administrative accounts shared by multiple humans who SSH in using this “user” (e.g. ubuntu is the default SSH account on AWS VMs running Ubuntu).
• root, which isn’t quite the same as any of the above.

These are four fairly different concepts, but in POSIX they are all “users”. As we’ll see later on, smashing all these concept into one vague concept called “user” can lead to many security problems.

But operationally, we don’t even have a way to say “only Alice and Bob can login to the shared admin account” within the boundaries of the POSIX user model.

SaaS providers don’t have “users”

Jeremy Green recently tweeted about the user model in Software-as-a-Service, and that is what first prompted me to write this post. His basic point is that SaaS services virtually always have:

1. A person at an organization who is paying for the service.
2. One or more people from that organization who actually use the service, together.

If you combine these into a single “User” at the start, you will be in a world of pain latter. You can’t model teams, you can’t model payment for multiple people at once—and now you need to retrofit your system. Now, you could learn this lesson for the SaaS case, and move on with your life.

But this is just a single instance of a broader problem: the concept “User” is too vague. If you start out being suspicious of the word “User”, you are much more likely to end up realizing you actually have two concepts at least: the Team (unit of payment and ownership) and the team Members (who actually use the service).

“Users” as a security problem

The word “users” isn’t just a problem for business logic: it also has severe security consequences. The word “user” is so vague that it conflates two fundamentally different concepts:

• A human being.
• Their representation within the software.

To see why this is a problem, let’s say you visit a malicious website which hosts an image that exploits a buffer overflow in your browser. The remote site now controls your browser, and starts uploading all your files to their server. Why can it do that?

Because your browser is running as your operating system “user”, which is presumed to be identical to you, a human being, a very different kind of “user”. You, the user, don’t want to upload those files. The operating system account, also the user, can upload those files, and since your browser is running under your user all its actions are presumed to be what you intended.

This is known as the Confused Deputy Problem. It’s a problem that’s much more likely to be part of your design if you’re using the word “user” to describe two fundamentally different things as being the same.

The value of up-front design

The key to being a productive programmer is getting the same work done with less effort. Using vague terms like “user” to model your software will take huge amounts of time and effort to fix later on. It may seem productive to start coding immediately, but it’s actually just the opposite.

Next time you start a new software project, spend a few hours up-front nailing down your terminology and concepts: you still won’t get it exactly right, but you’ll do a lot better. Your future self will thank you for the all the wasteful workaround work you’ve prevented.

There’s always too much work to do: too many features to implement, too many bugs to fix. And working evenings and weekends won’t help.

The real solution: you need to work fewer hours.

You want to work on cutting edge technology, you want challenging problems, you want something interesting. Problem is, you also want work/life balance: you don’t want to deal with unrealistic deadlines from management, or pulling all-nighters to fix a bug.

And the problem is that when you ask around, people tell say you need to work long hours if you want to work on challenging problems. That’s just how it is, they say.

To which I say: bullshit.

You can work on challenging problems and still have work/life balance. In fact, you’ll do much better that way.

My apparently impossible career so far

Just as a counter-example, let me tell you how I’ve spent the past 14 years. Among other things, I’ve worked on:

• A component of the flight search product that now powers Google Flights (flight search is hard—my team was working on the stuff on slides 44-48).
• The prototype for what was then cutting edge container storage technology, a prototype that helped my company raise a $12 million Series A—and then we turned it into a production ready distributed system.
• A crazy/useful Kubernetes local development tool.
• Most recently, scientific image processing algorithms and processing pipeline.

All of these were hard problems, and interesting problems, and challenging problems, and none of them required working long hours.

Maybe those past 14 years are some sort of statistical aberration, but I rather doubt it. You can, for example, go work on some really tricky distributed systems problems over at Cockroach Labs, and have Fridays off to do whatever you want. (Not a personal endorsement: I know nothing about them other than those two points.)

Long hours have nothing to do with interesting problems

There is no inherent relationship between interesting problems and working long hours. You’re actually much more likely to solve hard problems if you’re well rested, and have plenty of time off to relax and let your brain do its thing off in the background.

The real origin of this connection is a marketing strategy for a certain subset of startups: “Yes, we’ll pay you jack shit and have you work 70 hours a week, but that’s the only way you can work on challenging problems!”

This is nonsense.

The real problem that these companies are trying to solve is “how do I get as much work out of these suckers with as little pay as possible.” It’s an incompetent self-defeating strategy, but there’s enough VCs who think exploitation is a great business model that you’re going to encounter it at least some startups.

The reality is that working long hours is the result of bad management. Which is to say, it’s completely orthogonal to how interesting the problem is.

You can just as easily find bad management in enterprise companies working on the most pointless and mind-numbingly soul-crushing problems (and failing to implement them well). And because of that bad management you’ll be forced to work long hours, even though the problems aren’t hard.

Luckily, you can also find good management in plenty of organizations, big and small—and some of them are working on hard, challenging problems too.

Avoiding bad workplaces

So how do you avoid exploitative workplaces and find the good ones? By asking some questions up front. You shouldn’t be relying on luck to keep you away from bad jobs; I made that mistake once, but never again.

Long ago I was interviewing for a job in NYC, and I mentioned that I wanted to continue working on open source software in my spare time. Here’s how the rest of the conversation went:

Interviewer: “Well, that’s fine, but… we used to have an employee here who did some non-profit work. We could never tell if their mind was here or on their volunteering, and it didn’t really work out. So we want to make sure you’ll be really focused on your job.”

Me: “Did they do their volunteering during work hours?”

Interviewer: “Oh, no, they only did that on their own time, it was just that they left at 5 o'clock every day.”

At that point I realized that, while I was willing to exchange 40 hours a week for a salary, I was not willing to exchange my whole life. I escaped that company by accident because they were so blatant about it, but you can do better.

Finding the job you want

When you’re interviewing for a job, don’t just ask about the problems they’re working on. You should also be asking about the work environment and work/life balance.

You can do so tactfully and informatively by asking things like “What’s a typical work day like here?” or “How are deadlines determined?” (You can get a good list of questions over at Culture Queries.)

There are companies out there that do interesting work and have work/life balance: do your research, ask the right questions, and you too will be able to find them.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

It’s time for another deep-dive into Python brokenness and the pain that is POSIX system programming, this time with exciting and not very convincing shark-themed metaphors! Most of what you’ll learn isn’t really Python-specific, so stick around regardless and enjoy the sharks.

Let’s set the metaphorical scene: you’re swimming in a pool full of sharks. (The sharks are a metaphor for processes.)

Next, you take a fork. (The fork is a metaphor for fork().)

You stab yourself with the fork. Stab stab stab. Blood starts seeping out, the sharks start circling, and pretty soon you find yourself—dead(locked) in the water!

In this journey through space and time you will encounter:

• A mysterious failure wherein Python’s multiprocessing.Pool deadlocks, mysteriously.
• The root of the mystery: fork().
• A conundrum wherein fork() copying everything is a problem, and fork() not copying everything is also a problem.
• Some bandaids that won’t stop the bleeding.
• The solution that will keep your code from being eaten by sharks.

Let’s begin!

Introducing multiprocessing.Pool

Python provides a handy module that allows you to run tasks in a pool of processes, a great way to improve the parallelism of your program. (Note that none of these examples were tested on Windows; I’m focusing on the *nix platform here.)

from multiprocessing import Pool
from os import getpid

def double(i):
    print("I'm process", getpid())
    return i * 2

if __name__ == '__main__':
    with Pool() as pool:
        result = pool.map(double, [1, 2, 3, 4, 5])
        print(result)

If we run this, we get:

I'm process 4942
I'm process 4943
I'm process 4944
I'm process 4942
I'm process 4943
[2, 4, 6, 8, 10]

As you can see, the double() function ran in different processes.

Some code that ought to work, but doesn’t

Unfortunately, while the Pool class is useful, it’s also full of vicious sharks, just waiting for you to make a mistake. For example, the following perfectly reasonable code:

import logging
from threading import Thread
from queue import Queue
from logging.handlers import QueueListener, QueueHandler
from multiprocessing import Pool

def setup_logging():
    # Logs get written to a queue, and then a thread reads
    # from that queue and writes messages to a file:
    _log_queue = Queue()
    QueueListener(
        _log_queue, logging.FileHandler("out.log")).start()
    logging.getLogger().addHandler(QueueHandler(_log_queue))

    # Our parent process is running a thread that
    # logs messages:
    def write_logs():
        while True:
            logging.error("hello, I just did something")
    Thread(target=write_logs).start()

def runs_in_subprocess():
    print("About to log...")
    logging.error("hello, I did something")
    print("...logged")

if __name__ == '__main__':
    setup_logging()

    # Meanwhile, we start a process pool that writes some
    # logs. We do this in a loop to make race condition more
    # likely to be triggered.
    while True:
        with Pool() as pool:
            pool.apply(runs_in_subprocess)

Here’s what the program does:

1. In the parent process, log messages are routed to a queue, and a thread reads from the queue and writes those messages to a log file.
2. Another thread writes a continuous stream of log messages.
3. Finally, we start a process pool, and log a message in one of the child subprocesses.

If we run this program on Linux, we get the following output:

About to log...
...logged
About to log...
...logged
About to log...
<at this point the program freezes>

Why does this program freeze?

How subprocesses are started on POSIX (the standard formerly known as Unix)

To understand what’s going on you need to understand how you start subprocesses on POSIX (which is to say, Linux, BSDs, macOS, and so on).

1. A copy of the process is created using the fork() system call.
2. The child process replaces itself with a different program using the execve() system call (or one of its variants, e.g. execl()).

The thing is, there’s nothing preventing you from just doing fork(). For example, here we fork() and then print the current process’ process ID (PID):

from os import fork, getpid

print("I am parent process", getpid())
if fork():
    print("I am the parent process, with PID", getpid())
else:
    print("I am the child process, with PID", getpid())

When we run it:

I am parent process 3619
I am the parent process, with PID 3619
I am the child process, with PID 3620

As you can see both parent (PID 3619) and child (PID 3620) continue to run the same Python code.

Here’s where it gets interesting: fork()-only is how Python creates process pools by default.

The problem with just fork()ing

So OK, Python starts a pool of processes by just doing fork(). This seems convenient: the child process has access to a copy of everything in the parent process’ memory (though the child can’t change anything in the parent anymore). But how exactly is that causing the deadlock we saw?

The cause is two problems with continuing to run code after a fork()-without-execve():

1. fork() copies everything in memory.
2. But it doesn’t copy everything.

fork() copies everything in memory

When you do a fork(), it copies everything in memory. That includes any globals you’ve set in imported Python modules.

For example, your logging configuration:

import logging
from multiprocessing import Pool
from os import getpid

def runs_in_subprocess():
    logging.info(
        "I am the child, with PID {}".format(getpid()))

if __name__ == '__main__':
    logging.basicConfig(
        format='GADZOOKS %(message)s', level=logging.DEBUG)

    logging.info(
        "I am the parent, with PID {}".format(getpid()))

    with Pool() as pool:
        pool.apply(runs_in_subprocess)

When we run this program, we get:

GADZOOKS I am the parent, with PID 3884
GADZOOKS I am the child, with PID 3885

Notice how child processes in your pool inherit the parent process’ logging configuration, even if that wasn’t your intention! More broadly, anything you configure on a module level in the parent is inherited by processes in the pool, which can lead to some unexpected behavior.

But fork() doesn’t copy everything

The second problem is that fork() doesn’t actually copy everything. In particular, one thing that fork() doesn’t copy is threads. Any threads running in the parent process do not exist in the child process.

from threading import Thread, enumerate
from os import fork
from time import sleep

# Start a thread:
Thread(target=lambda: sleep(60)).start()

if fork():
    print("The parent process has {} threads".format(
        len(enumerate())))
else:
    print("The child process has {} threads".format(
        len(enumerate())))

When we run this program, we see the thread we started didn’t survive the fork():

The parent process has 2 threads
The child process has 1 threads

The mystery is solved

Here’s why that original program is deadlocking—with their powers combined, the two problems with fork()-only create a bigger, sharkier problem:

1. Whenever the thread in the parent process writes a log messages, it adds it to a Queue. That involves acquiring a lock.
2. If the fork() happens at the wrong time, the lock is copied in an acquired state.
3. The child process copies the parent’s logging configuration—including the queue.
4. Whenever the child process writes a log message, it tries to write it to the queue.
5. That means acquiring the lock, but the lock is already acquired.
6. The child process now waits for the lock to be released.
7. The lock will never be released, because the thread that would release it wasn’t copied over by the fork().

In simplified form:

from os import fork
from threading import Lock

# Lock is acquired in the parent process:
lock = Lock()
lock.acquire()

if fork() == 0:
    # In the child process, try to grab the lock:
    print("Acquiring lock...")
    lock.acquire()
    print("Lock acquired! (This code will never run)")

Band-aids and workarounds

There are some workarounds that could make this a little better.

For module state, the logging library could have its configuration reset when child processes are started by multiprocessing.Pool. However, this doesn’t solve the problem for all the other Python modules and libraries that set some sort of module-level global state. Every single library that does this would need to fix itself to work with multiprocessing.

For threads, locks could be set back to released state when fork() is called (Python has a ticket for this.) Unfortunately this doesn’t solve the problem with locks created by C libraries, it would only address locks created directly by Python. And it doesn’t address the fact that those locks don’t really make sense anymore in the child process, whether or not they’ve been released.

Luckily, there is a better, easier solution.

The real solution: stop plain fork()ing

In Python 3 the multiprocessing library added new ways of starting subprocesses. One of these does a fork() followed by an execve() of a completely new Python process. That solves our problem, because module state isn’t inherited by child processes: it starts from scratch.

Enabling this alternate configuration requires changing just two lines of code in your program:

from multiprocessing import get_context

def your_func():
    with get_context("spawn").Pool() as pool:
        # ... everything else is unchanged

That’s it: do that and all the problems we’ve been going over won’t affect you. (See the documentation on contexts for details.)

But this still requires you to do the work. And it requires every Python user who trustingly follows the examples in the documentation to get confused why their program sometimes breaks.

The current default is broken, and in an ideal world Python would document that, or better yet change it to no longer be the default.

Learning more

My explanation here is of course somewhat simplified: for example, there is state other than threads that fork() doesn’t copy. Here are some additional resources:

• Read the Linux man page for fork() to learn about other things it doesn’t copy.
• Rachel By The Bay’s post on why threads and processes don’t mix and a followup are where I originally learned about this problem—and I promptly forgot about it until I encountered a related issue in production code.
• Some mathematical analysis of your chances of getting eaten by a shark and a followup.

Stay safe, fellow programmers, and watch out for sharks and bad interactions between threads and processes! 🦈🦑

(Want more stories of software failure? I write a weekly newsletter about 20+ years of my mistakes as a programmer.)

Thanks to Terry Reedy for pointing out the need for if __name__ == '__main__'.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

(Thanks to Mark Rice for his helpful suggestions. Any mistakes or omissions that remain are my responsibility.)

Some Python projects are designed to be libraries, consumed by other projects. These are most of the things people consider "Python projects": for example, Twisted, Flask, and most other open source tools. However, things like mu are sometimes installed as an end-user artifact. More commonly, many web services are written as deployable Python applications. A good example is the issue tracking project trac.

Projects that are deployed must be deployed with their dependencies, and with the dependencies of those dependencies, and so forth. Moreover, at deployment time, a specific version must be deployed. If a project declares a dependency of flask>=1.0.1, for example, something needs to decide whether to deploy flask 1.0.1 or flask 1.0.2.

For clarity, in this text, we will refer to the declared compatibility statements in something like setup.py (e.g., flask>=1.0.1) as "intent" dependencies, since they document programmer intent. The specific dependencies that are eventually deployed will be referred as the "expressed" dependencies, since they are expressed in the actual deployed artifact (for example, a Docker image).

Usually, "intent" dependencies are defined in setup.py. This does not have to be the case, but it almost always is: since there is usually some "glue" code at the top, keeping everything together, it makes sense to treat it as a library -- albeit, one that sometimes is not uploaded to any package index.

When producing the deployed artifact, we need to decide on how to generate the expressed dependencies. There are two competing forces. One is the desire to be current: using the latest version of Django means getting all the latest bug fixes, and means getting fixes to future bugs will require moving less versions. The other is the desire to avoid changes: when deploying a small bug fix, changing all library versions to the newest ones might introduce a lot of change.

For this reason, most projects will check in the "artifact" (often called requirements.txt) into source control, produce actual deployed versions from that, and some procedure to update it.

A similar story can be told about the development dependencies, often defined as extra [dev] dependencies in setup.py, and resulting in a file dev-requirements.txt that is checked into source control. The pressures are a little different, and indeed, sometimes nobody bothers to check in dev-requirements.txt even when checking in requirements.txt, but the basic dynamic is similar.

The worst procedure is probably "when someone remembers to". This is not usually anyone's top priority, and most developers are busy with their regular day-to-day task. When an upgrade is necessary for some reason -- for example, a bug fix is available, this can mean a lot of disruption. Often this disruption manifests in that just upgrading one library does not work. It now depends on newer libraries, so the entire dependency graph has to be updated, all at once. All intermediate "deprecation warnings" that might have been there for several months have been skipped over, and developers are suddenly faced with several breaking upgrades, all at once. The size of the change only grows with time, and becomes less and less surmountable, making it less and less likely that it will be done, until it ends in a case of complete bitrot.

Sadly, however, "when someone remembers to" is the default procedure in the absence of any explicit procedure.

Some organizations, having suffered through the disadvantages of "when someone remembers to", decide to go to the other extreme: avoiding to check in the requirements.txt completely, and generating it on every artifact build. However, this means causing a lot of unnecessary churn. It is impossible to fix a small bug without making sure that the code is compatible with the latest versions of all libraries.

A better way to approach the problem is to have an explicit process of recalculating the expressed dependencies from the intent dependencies. One approach is to manufacture, with some cadence, code change requests that update the requirements.txt. This means they are resolved like all code changes: review, running automated tests, and whatever other local processes are implemented.

Another is to do those on a calendar based event. This can be anything from a manually-strongly-encouraged "update Monday", where on Monday morning, one of a developer tasks is to generate a requirements.txt updates for all projects they are responsible for, to including it as part of a time-based release process: for example, generating it on a cadence that aligns with agile "sprints", as part of the release of the code changes in a particular sprints.

When updating does reveal an incompatibility it needs to be resolved. One way is to update the local code: this certainly is the best thing to do when the problem is that the library changed an API or changed an internal implementation detail that was being used accidentally (...or intentionally). However, sometimes the new version has a bug in it that needs to be fixed. In that case, the intent is now to avoid that version. It is best to express the intent exactly as that: !=<bad version>. This means when an even newer version is released, hopefully fixing the bug, it will be used. If a new version is released without the bug fix, we add another != clause. This is painful, and intentionally so. Either we need to get the bug fixed in the library, stop using the library, or fork it. Since we are falling further and further behind the latest version, this is introducing risk into our code, and the increasing != clauses will indicate this pain: and encourage us to resolve it.

The most important thing is to choose a specific process for updating the expressed dependencies, clearly document it and consistently follow it. As long as such a process is chosen, documented and followed, it is possible to avoid the bitrot issue.

You’ve discovered you’re underpaid. Maybe you found out a new hire is making more than you. Or maybe you’ve been doing a great job at work, but your compensation hasn’t changed.

Whatever the reason, you want to get a higher salary.

Now what?

To answer that question, the following guest post by Adrienne Bolger will explain how you can negotiate a raise at your current job. As you’ll see, she’s successfully used these strategies to negotiate 20-30% raises on multiple occasions.

❧

This article will answer some common questions, and explain some useful strategies, to help you—a software engineer—engineer a raise from your employer. I’ll cover:

1. Researching your worth and options.
2. Expectation setting.
3. Strategies that I have used—and helped others use—to ask for a raise.

How much are you “worth”?

At the end of the day, an optimized salary in a more-or-less capitalist market is the highest salary you think you can get that passes the “laugh test.” If you ask for a salary or bonus, and your (theoretical) boss or HR head laughs in your face, then the number is too high.

Note that this number isn’t your laugh test number: many people, out of fear of rejection, are afraid to ask for a 25% raise rather than a more “modest” sounding 5% raise. But sometimes the 25% value is the right increase! Your number should not be based on fear: it should be based on research.

There are several ways to calculate your “market value” to an employer. To start, take 2 or 3 of the following quizzes to calculate median/mean salaries based on your demographics:

• StackOverflow calculator - I recommend starting with this one.
• Glassdoor calculator - this one will be helpful for engineers working at a company large enough that they can get their own company data from it.
• PayScale calulator
• Job Search Intelligence

How much could you be worth in the future?

Take the surveys a second time. However, this time, give yourself a small imaginary promotion: 2 years more experience and the next job title you want—Senior Engineer, Engineer II, Software Architect, Engineering Manager, Director, whatever it is. How far away is that yearly salary amount from the first one? A little? A lot?

This is an important number, because the pay market for software engineers is not linear. Check out this graph created by ArsTechnica from the 2017 Stack Overflow salary data.

This graph shows the economics of a very hot job market: people with relatively little experience still make a good living, because their skills are in high demand. However, the median salary for a developer between 15 and 20 years of experience is completely flat. This isn’t the best news for experienced developers who haven’t kept learning (and some languages pay more than others), but for early career professionals, this external market factor is fantastic.

With data to back you up, you can ask for a 20 to 30% raise after only a year or two on the job with a completely straight face. I did it in my own career at the 2 and 4 year marks at the same company, and received the raise both times.

Adjust expectations for your company and industry

If you’ve come to the conclusion you are underpaid because you know what your colleagues earn, then you can skip this step. Otherwise, you have a little more research to do.

Ask your company’s HR department and recruiters: when hiring in general, does your company go for fair market prices, under-market bargains, or above-market talent? Industries like finance pay better than non-profits and civil service organizations whether you are an engineer or an accountant.

The bigger the company, the more likely you are to get standard yearly pay adjustments for things like cost-of-living expenses, but a bigger company is also likely more rigid in salary bands for a specific job title. HR at your company may or may not be willing to share the exact high and low range for a job title. If they are not, Glassdoor can provide a decent estimate for similarly size companies.

When to ask

Again, know your company. Does it have a standard financial cycle, with cost-of-living and raises allocated yearly 1-2 months after reviews are in?

If so, time your “ask” before your formal review by 3-8 weeks. That might be November if your yearly reviews are in December, or it might be January if company yearly performance reviews occur in March, after the fiscal year results from last year are in.

Why do this?

The problem with waiting until a formal review is scheduled is that is ruins plans you can’t see or are not privy to. Even in the best case where you were getting a raise anyway, the manager giving your review already has a planned number in their head and their accounting software. Asking a month beforehand gives your boss time to budget your raise into a yearly plan, which is much easier than trying to fight bureaucracy out-of-cycle.

You should not ask for a raise more frequently than every 2 years. If you feel like you have to, then you probably didn’t ask for enough last time. Consider that if you find yourself afraid to ask for as much.

If you are debating between asking for a raise and going job hunting because you feel undervalued, ask for the raise first. I suggest this because job searching is a huge time sink, especially if you don’t really want to change jobs.

You owe it to yourself to proactively seek happiness. If what you really want is more money and to stay at your current company, then give your employer a chance to make you happy. If you ask and are denied, then at least you’ve done all the research into compensation when you go looking.

How to ask

Ask for a raise both in writing and in person.

As email is still considered informal, this is one of those cases where an actual letter—printed out and hand-delivered to a scheduled meeting with your manager—is a good idea. The meeting gives the chance to explain what you want a little more, but the letter is a written record of what you want that goes to HR, as well as a way to keep yourself from backing out due to nerves or stress.

I once requested a raise from a manager who (unbeknownst to me) was let go 2 weeks later. However, because my raise request was also in writing, I received the raise from my new boss with no confusion after the transfer.

The letter should be 2-3 paragraphs long and:

• Be addressed and CC’d to your manager and HR at your company.
• List your current length of service with the company and affirm that you like working there.
• Detail exactly what you want: a 20% raise? A $5,000 raise? Tuition money for school? More vacation days? Do not leave it ambiguous.
• Detail why you believe you deserve it, and back it up with available data:
  • Do you have more experience now?
  • Earned a degree?
  • Learn new skills or programming language?
  • Has it been 3 years since you got a review because you work at a 20 person startup?
• The exception to the previous point is if you know you are underpaid because a coworker with the same responsibilities is paid more: it’s enough to say that in general terms. Calling a specific coworker out is unnecessary.
• List, in 2 sentences or less, any recent accomplishments that were especially impactful. This serves 2 purposes: reminding your boss how awesome you are, but also making it easy on them to justify your (deserved) raise to the people they are accountable to at the next level up in the company.
• End with a request for a meeting discussing the contents of the letter.
• Be signed and dated.

The letter (and subsequent meeting) should not:

• Imply you will leave if you don’t get what you want, even if you are planning on it. Bluffing here is a good way to get asked to leave anyway. Even if you are planning to leave if you don’t receive a raise, threats put people on the defensive.
• Sound angry or imply you have an ungrateful or deficient manager/employer. Position yourself as asking for something a reasonable person should want to give you. Have the most gentle and peaceful individual you know read your letter to double check tone. If all else fails, try your local Buddhist monk.

The meeting

Once you ask for a raise and a meeting to talk about it, nerves may kick in. Do your homework ahead of time and come in prepared. Bring a copy of your letter and, during the meeting, re-iterate exactly what it is you want and why you deserve it.

It’s fine to be nervous, but do not attempt any weird “Hollywood caricature of a car salesman” negotiating tactics. Don’t be short-sighted; remember that you have to perform your day job with your manager once the meeting is over.

If your employer declines

If you asked for your “laugh test” number and your employer can only meet you halfway or can’t increase your compensation at all, your response should be “Why? And what can I do to change that?”

Be proactive in determining where the problem is. At a big company, if there’s a salary band, you may need a promotion before you can get the raise. If the company isn’t making enough money for raises for anyone, it may be time to discreetly look for another job anyway.

Whether or not you choose to accept a compromise or counteroffer is up to you—but make sure that you can live with your choice, at least short term, because it won’t make sense to ask again for another few months.

❧

And that’s Adrienne’s post. I hope you found it useful: I certainly learned a lot from it.

Of course, reading this article isn’t enough. You still need to go and do the work to get the raise. So why not start today?

1. Do your research.
2. Pick the right moment.
3. Go ask for that raise!

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

You’ve got plenty of work to do already, when your boss (or their boss, or the CEO) comes by and asks you to do yet another task. If you take yet another task on you’re going to be working long hours, or delivering your code late, and someone is going to be unhappy.

You don’t want to say no to your boss (let alone the CEO!). You don’t want to say yes and spend your weekend working.

What do you do? How do you keep everyone happy?

What you need is your management to trust your judgment. If they did, you could focus on the important work, the work that really matters. And when you had to say “no”, your boss (or the CEO!) would listen and let you continue on your current task.

To get there, you don’t immediately say “no”, and don’t immediately say “yes”.

Here’s what you do instead:

1. Start with your organizational and project goals.
2. Listen and ask questions.
3. Make a decision.
4. Communicate your decision in terms of organizational and project goals.

Step 1: Start with you goals

If you want people to listen to you, you need a strong understanding of why you’re doing the work you’re doing.

• What is your organization trying to achieve?
• What is your project trying to achieve, and how does that connect to organizational goals?
• How does your work connect to the project goals?

You should be able to connect your individual action to project success, and connect that to organizational success. For example, “Our goal is to increase recurring revenue, customer churn is too high and it’s decreasing revenue, so I am working on this bug because it’s making our product unusable for at least 7% of users.”

When you’re just starting out as an employee this can be difficult to do, but as you grow in experience you can and should make sure you understand this.

(Starting with your goals is useful in other ways as well, e.g. helping you stay focused).

Step 2: Listen and ask questions

Your lead developer/product manager/team mate/CEO/CTO had just stopped by your desk and given you a new task. No doubt you already have many existing tasks. How should you handle this situation?

To begin with, don’t immediately give an answer:

• Don’t immediately say “yes”: Unless you happen to have no existing work, any new work you take on will slow down your existing work. Your existing work was chosen for a reason, and may well be more important than this new task.
• Don’t immediately say “no”: There’s a reason you’re being asked to do this task. By immediately saying “no” you are devaluing the request, and by extension devaluing the person who asked you.

Instead of immediately agreeing or disagreeing to do the task, take the time find out why the task needs to be done. Make sure you demonstrate you actually care about the request and are seriously considering it.

That means first, listening to what they have to say.

And second, asking some questions: why does this need to be done? What is the deadline? How important is it to them?

Sometimes the CEO will come by and ask for something they don’t really care about: they only want you to do it if you have the spare time. Sometimes your summer intern will come by and point out a problem that turns out to be a critical production-impacting bug.

You won’t know unless you listen, and ask questions to find out what’s really going on.

Step 3: Decide based on your goals

Is the new task more important to project and organizational goals than your current task? You should probably switch to working on it.

Is the new task less important? You don’t want to do it.

Not sure? Ask more questions.

Still not sure? Talk to your manager about it: “Can I get back to you in a bit about this? I need to talk this over with Jane.”

Step 4: Communicate your decision

Once you’ve made a decision, you need to communicate it in a meaningful, respectful way, and in a way that reflects organizational and project goals.

If you decided to take the task on:

1. Tell the person asking you that you’ll take it on.
2. Explain to the people who requested your previous tasks that those tasks will be late. Make sure it’s clear why you took on a new task: “That feature is going to have to wait: it’s fairly low on the priority list, and the CEO asked me to throw together a demo for the sales meeting on Friday.”

If you decided not to take it on:

1. Explain why you’re not going to do it, in the context of project and organizational goals. “That’s a great feature idea, and I’d love to do it, but this bug is breaking the app for 10% of our customers and so I really need to focus on getting it done.”
2. Provide an alternative, which can include:
   • Deflection: “Why don’t you talk to the product manager about this?”
   • Queuing: “Why don’t you add it to the backlog, and we can see if we have time to do it next sprint?”
   • Promise: “I’ll do it next, as soon as I’m done with my current task.”
   • Reminder: “Can you remind me again in a couple of weeks?”
   • Different solution: “Your original proposal would take me too long, given the release-blocker backlog, but maybe if we did this other thing instead I could fit it in. It seems like it would get us 80% of the functionality in a fraction of the time–what do you say?”

Becoming a more valuable employee

Saying “no” the right way makes you more valuable, because it ensures you’re working on important tasks.

It also ensures your managers know you’re more valuable, because you’ve communicated that:

1. You’ve carefully and respectfully considered their request.
2. You’ve taken existing requests you’re already working on into account.
3. You’ve made a decision not based on personal whim, but on your best understanding of what is important to your project and organization.

Best of all, saying “no” the right way means no evenings or weekends spent working on tasks that don’t really need doing.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

Have you ever wished you could reduce your working hours, or even just limit yourself to 40 hours a week, but came up against all the work that just needs doing? There’s always more work to do, always more bugs, always some feature that’s important to someone—

How can you limit yourself to 40 hours a week, let alone a shorter workweek, given all this work?

The answer: by planning ahead. And planning ahead the right way.

The wrong way to plan

I was interviewing for a job at a startup, and my first interviewer was the VP of Engineering. He explained that he’d read my blog posts about the importance of work/life balance, and he just wanted to be upfront about the fact they were working 50-60 hours each week. And this wasn’t a short-term emergency: in fact, they were going to be working long hours for months.

I politely noted that I felt good prioritization and planning could often reduce the need for long hours.

The VP explained the problem: they’d planned all their tasks in detail. But then—to their surprise—an important customer asked for more features, and that blew through their schedule, which is why they needed to work long hours.

I kept my mouth shut and went through the interview process. But I didn’t take the job.

Here’s what’s wrong with this approach:

1. Important customers asking for more features should not be a surprise. Customers ask for changes, this is how it goes.
2. More broadly, the original schedule was apparently created with the presumption that everything would go perfectly. In the real world nothing ever goes perfectly.
3. When it became clear that that there was too much work to do, their solution was to work longer hours, even though research suggests that longer hours do not increase output over the long term.

The better way: prioritization and padding

So how do you keep yourself from blowing through your schedule without working long hours?

1. Prioritize your work.
2. Leave some padding in your schedule for unexpected events.
3. Set your deadlines shorter than they need to be.
4. If you run out of time, drop the least important work.

1. Prioritize your work

Not all work is created equal. By starting with your goals, you can divide tasks into three buckets:

1. Critical to your project’s success.
2. Really nice to have—but not critical.
3. Clearly not necessary.

Start by dropping the third category, and minimizing the second. You’ll have to say “no” sometimes, but if you don’t say “no” you’ll never get anything delivered on time.

2. Leave some padding in your schedule

You need to assume that things will go wrong and you’ll need extra time to do any given task. And you need to assume other important tasks will also become critical; you don’t know which, but this always happens. So never give your estimate as the actual delivery date: always pad it with extra time for unexpected difficulties and unexpected interruptions.

If you think a task will take a day, promise to deliver it in three days.

3. Set shorter deadlines for yourself

Your own internal deadline, the one you don’t communicate to your boss or customer, should be shorter than your estimate. If you think a task will take a day, try to finish it in less time.

Why?

• You’ll be forced to prioritize even more.
• With less time to waste on wrong approaches, you’ll be forced to spend more time upfront thinking about the best solution.

4. When you run out of time, drop the less important work

Inevitably things will still go wrong and you’ll find yourself running low on time. Now’s the time to drop all the nice-to-haves, and rethink whether everything you thought was critical really is (quite often, it’s not).

Long hours are the wrong solution

Whenever you feel yourself with too much work to do, go back and apply these principles: underpromise, limit your own time, prioritize ruthlessly. With practice you’ll learn how to deliver the results that really matter—without working long hours.

When you’ve reached that point, you can work a normal 40-hour workweek without worrying. Or even better, you can start thinking about negotiating a 3-day weekend.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

There are many wordy articles on configuring your web server’s TLS ciphers. This is not one of them. Instead I will share a configuration which is both compatible enough for today’s needs and scores a straight “A” on Qualys’s SSL Server Test.

(Thanks to Avy Faingezicht and Donald Stufft for giving me encouragement and feedback. All mistakes that remain are mine.)

"eyes have they, but they see not" -- Psalms, 135:16

Eyes are expensive to maintain. They require protection from the elements, constant lubrication, behavioral adaptations to protect them and more. However, they give us a benefit. They allow us to see: to detect differences in the environment. Eyes register different signals when looking at an unripe fruit and when looking at a ripe fruit. This allows us to eat the ripe fruit, and wait for the unripe fruit to ripen: to behave differently, in a way that ultimately furthers our goals (eat yummy fruits).

If our eyes did not get different signals that influenced our behavior, they would not be cost effective. Evolution is a harsh mistress, and the eyes would be quickly gone if the signals from them were not valuable.

Writing tests is expensive. It takes time to write them, time to review them, time to modify them as code evolves. A test that never fails is like an eye that cannot see: it always sends the same signal, "eat that fruit!". In order to be valuable, a test must be able to fail, and that failure must modify our behavior.

The only way to be sure that a test can fail is to see it fail. Test-driven-development does it by writing tests that fail before modifying the code. But even when not using TDD, making sure that tests fail is important. Before checking in, break your code. Best of all is to break the code in a way that would be realistic for a maintenance programmer to do. Then run the tests. See them fail. Check it in to the branch, and watch CI fail. Make sure that this CI failure is clearly communicated: something big must be red, and merging should be impossible, or at least require using a clearly visible "override switch".

If there is no code modification that makes the test fail, of if such code modification is weird or unrealistic, it is not a good test. If a test failure does not halt the CI with a visible message, it is not a good CI. These are false gods, with eyes that do not see, and mouths that do not speak.

Real tests have failures.

When I was in my early 20s, I was OK at programming, but I definitely didn't like it. Then, one evening, I read the Python tutorial. That evening changed my mind. I woke up the next morning, like Neo in the matrix, and knew Python.

I was doing statistics at the time. Python, with Numeric, was a powerful tool. It definitely could do things that SPSS could only dream about. Suddenly, something has happened that never happened before -- I started to enjoy programming.

I had to spend six years in the desert of programming in languages that were not Python, before my work place, and soon afterwards the world, realized what an amazing tool Python is. I have not had to struggle to find a Python position since.

I started with Python 1.4. I have grew up with Python. Now I am...no longer in my 20s, and Python version 3.7 was recently released.

I owe much of my career, many of my friends, and much of my hobby time to that one evening, sitting down and reading the Python tutorial -- and to the man who made the language and wrote the first version of that tutorial, Guido van Rossum.

Python, like all open source projects, like, indeed, all software projects, is not a one man show. A whole team, with changing personnel, works on core Python and its ecosystem. But it was all started by Guido.

As Guido is stepping down to take a less active role in Python's future, I want to offer my eternal gratitude. For my amazing career, for my friends, for my hobby. Thank you, Guido van Rossum. Your contribution to humanity, and to this one human in particular, is hard to overestimate.

Practicing algorithm puzzles stresses you out: just looking at a copy of Cracking the Coding Interview makes you feel nervous.

Interviewing is worse. When you do interview you freeze up: you don’t have IDE error checking and auto-completion, you can’t use a search engine Google like a real programmer would, there’s a stranger staring you down. You screw up, you make typos, you don’t know what to say, you make a bad impression.

If this happens to you, it’s not your fault! Whiteboard puzzles are a bad way to hire programmers.

They’re not realistic: unless you’re Jeff Goldblum haxoring the alien mothership’s computer just in time for Will Smith to blow up some invaders, you’re probably not coding on a 5-minute deadline.

And the skills they’re testing aren’t used by 95% of programmers 95% of the time. I recently had to do a graph traversal in dependency order—which meant I was all prepared to find my algorithms text book from college. But then I found this library already had a utility called toposort, and vague memories of classes 19 years ago reminded me that this was called a “topological sort”. I didn’t actually have to implement it, but if I did would have done it with textbook in hand, over the course of a couple of hours (gotta write tests!).

Unfortunately, many companies still use them, and you need a job. A programming job. What should you do?

Here are some ideas to help you find a job—even if you hate whiteboard puzzles.

1. Interview at companies with a better process

Not all companies do on-the-spot programming puzzles. The last three companies I worked at didn't—one had a take-home exercise that wasn’t about algorithms (a decision I was involved in, and which I now regret because of the burden it puts on people with no free time). Two others just had talking interviews: I talked about myself, they talked about the company, all very relaxes and civilized.

To find such companies:

1. Here’s one list of 500+ companies that don’t do whiteboard puzzles.
2. The invaluable Key Values job board also tells you about the interview process at the covered companies (see the column on the right when looking at a particular company).

2. Offer an alternative

If you are interviewing at a company with whiteboard puzzles, you don’t have to accept their process without pushing back. Just like your salary and working hours, the interview process is also something you can negotiate.

If you have some code you’ve written that you’re particularly proud of and have the ability to share, ask the company if you can share it with them in lieu of a whiteboard puzzle. I once made the mistake of only suggesting this during the interview, and the guy who was interviewing me said he would have accepted it if I’d asked earlier. So make sure to suggest this before the day of the interview, so they have time to review the code in advance.

3. Take control of the process

If all else fails and you’re stuck doing a puzzle, there are ways to take control of the process and make a good impression, even if the puzzle is too hard for you. I cover this in more detail in another post.

4. Don’t give up

Finally, remember whiteboard puzzles have nothing to do with actual programming, even when the work you’re doing is algorithmic. They’re a hazing ritual you may be forced to go through, but they in no way reflect on your ability as a programmer.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

If you want to limit your working hours as a programmer you need to keep your boss happy. But what can you do if your boss seems to care more about your time in the office than how much you produce?

Not to mention the comparison to your other coworkers. If they fix ten bugs a week, but you only fix two, your boss might not be happy—even if the bugs you fixed had far more impact, and were much harder to address.

If you’re stuck in this situation it may seem impossible to reduce your working hours. But before you give up and start looking for another job, it’s worth seeing if you can improve the situation where you are.

Two reasons your boss might like long hours

If you’re going to be judged by hours you need a manager who cares about the organization’s or team’s goals. There are two possibilities about how your boss is thinking:

Hours as proxy: Your boss cares about achieving goals, and is using hours as a mental shorthand for value produced. If you actually are a valuable worker, and make sure they know it, they won’t notice your working hours, as in this real occurrence:

A programmer I know was having a conversation with their manager when the manager mentioned, in an offhand manner, that the company expected people to work 50 hours a week.

This programmer had always worked 40-45 hours a week, and the manager had never complained or noticed, because the programmer did good work. So the programmer kept their mouth shut, didn’t comment, and kept on working their usual hours.

Hours as goal: Your boss may truly only care about hours in the office number of bugs fixed, or some other irrelevant measure. Which is to say, they’re incompetent. In this case the suggestion that follows won’t work, unless perhaps you can bypass your boss and reach someone who does care about organizational goals. Usually a job with different team or organization will serve you better.

Assuming your boss only uses hours as a proxy measure, let’s see what you can do.

Starting with goals

It’s 3PM on a Wednesday, and your boss swings by your desk and asks how things are going. You explain you’re upgrading one of your JavaScript dependencies.

Your boss nods and wanders off, wondering if you’re actually doing anything worthwhile. You have just wasted an opportunity to demonstrate your value.

What’s the alternative? Starting with goals in mind.

Elsewhere I’ve talked about how starting with goals in mind will keep you focused, and is key to making you more productive. Starting with your organizational and team goals in mind can also help you both choose valuable work and explain its value to your boss.

For every task you work on, you should have a clear logical path from the big picture organizational goals, down to your team’s goals, down to your project’s goals, down to why this particular task at this particular time is a good way to advance those goals. If you can’t make that connection, if you can’t explain why you’re doing what you’re doing:

1. You may not actually be doing anything valuable.
2. Even if you are, you can’t prove it.

Let’s get back to that JavaScript dependency. If you started with goals in mind you might have decided this wasn’t a particularly useful task to begin with, and worked on something else. Or, perhaps you know exactly why you’re doing it.

In that case, the conversation might go something like this:

“You know how we’ve decided we wanted to increase user retention? Well, it looks like one of the problems is that our site is rendering way too slowly, so half our users bounce before the page finishes loading.

Turns out that font loading is the problem, and this library has a feature to fix that in its latest release. Once I’ve upgraded I should be able to get pages to render in a quarter of the time, and I’m hoping that’ll increase user retention. And I have some other ideas in case that isn’t sufficient.”

Your boss goes away understanding that what you’re doing is valuable. And if they’re anywhere near competent they won’t be thinking about the bug queue, or how many hours they’ve seen you in the office. They’ll be thinking about the good work you’re doing, and how they can tell their boss that the retention problem is being addressed.

Communicating your value based on goals

You can explain your work in this way when asked, but there’s no reason not to do so proactively as well. Once a week, or once a month, you can take stock of what you’ve achieved and send an email to your boss. And you can also keep a copy of this email to update your resume when the time comes to look for a new job.

To recap:

1. Understand why you’re doing your work.
2. Choose work that addresses those goals.
3. Communicate to your boss why your work is helping those goals.

This will shift many managers from a hour mindset—driven by an assumption that your work isn’t producing that much value—to a value mindset. Your boss will know your output is valuable, and as a result won’t require the proxy measure of hours worked.

Learning how to work towards goals is, of course, easier said than done. It took me many years and many mistakes along the way. If you’d like to accelerate your learning, and take advantage of everything I’ve learned working as a programmer over the past 20 years, you can sign up for my Software Clown weekly newsletter. Every week I share a mistake and what you can learn from it.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

You’re tired of working yourself to death. You’ve had enough of the pressure of long hours, and you want not more money but more time: you want a shorter workweek. You want to work 35 hours a week, or 32, or even less.

But in an industry where some companies brag about their 70-hour workweeks, can you find a programming job with a short workweek?

The short answer is that yes, you can work 35 hours or less. I’ve done it at multiple jobs, and I know other programmers who do so as well.

The longer answer is that you have multiple different options, different ways of achieving this goal. Let’s see what they are.

Option #1: Find a job that offers shorter hours

While they are few and far between, some organizations do offer shorter workweeks. For example, over on the excellent Key Values job board you can learn about Monograph, a company that provides a 32-hour workweek by default.

Option #2: Negotiate a custom deal

Just like you can negotiate a higher salary, you can also negotiate a shorter workweek. The best place to do it is at your current job, because you’ve likely got expensive-to-replace knowledge of business logic, organizational procedures, local tech stack, and so on. But you can also negotiate for a shorter workweek at a new job, if you do it right.

If you’re interested in seeing how this is done, read my interview with a programmer who has been working part-time for 15 years.

Option #3: Become a consultant (the right way)

If you’re a consultant and you do it right, you can raise your rates high enough that you don’t need to work full time to make a living. Doing it right is important, though: if your hourly rate is low enough you’re going to have to work long hours.

To learn about some of what it takes, Jonathan Stark’s Value Pricing Bootcamp is one place to start.

Option #4: Start a product business (the right way)

If you’re selling a product that you’ve created, the hours you work don’t map one-to-one to your income. You have the upfront time for creating the product, and ongoing time for marketing and maintaining the product, but at that point you can sell the same product over and over with much smaller investment of time.

Consider for example Amy Hoy’s explanation of how bootstrapping a business allowed her to make a living even with a chronic illness.

Option #5: Early retirement

Living below your means is a good idea in general: the more money you have in the bank the easier it’ll be for you to find a better job, for example. But if you don’t want to work at all, over the long term cutting your expenses can help you stop working altogether.

Liberate yourself from the office

One of the pernicious side-effects of the culture of long hours in tech is that even a 40-hour workweek seems impossible. But long hours aren’t necessary: they’re a crutch for bad management. Working shorter hours can actually make you more productive, productive enough that your total output goes up even with shorter hours.

In the short run, if you want to work fewer hours you have to do something about it.

In the long run, there’s no reason why a 32-hour workweek couldn’t be the standard—if we all push for it hard enough.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

A common way to expose an API in Python is as inheritance. Though many projects do that, there is a better way.

But first, let's see. How popular is inheritance-as-an-API, anyway?

Let's go to the Twisted website. Right at the center of the screen, at prime real-estate, we see:

What's there? The following is abridged:

class Echo(protocol.Protocol):
    def dataReceived(self, data):
        self.transport.write(data)
class EchoFactory(protocol.Factory):
    def buildProtocol(self, addr):
        return Echo()

(This is part of an example on building an echo-server protocol.)

If you are wondering who came up with this amazing API, it is the same person who is writing the words you are reading. I certainly thought it was an amazing API!

Look at how many smart people agreed with me.

Django takes a page of tutorial to get there, but sure enough:

class Question(models.Model):
    question_text = models.CharField(max_length=200)
    pub_date = models.DateTimeField('date published')
class Choice(models.Model):
    question = models.ForeignKey(Question, on_delete=models.CASCADE)
    choice_text = models.CharField(max_length=200)
    votes = models.IntegerField(default=0)

Jupyter's echo kernel starts:

class EchoKernel(Kernel):
    implementation = 'Echo'
    implementation_version = '1.0'
    language = 'no-op'

Everyone is doing it. A project I have been a developer on for ~16 years. The most popular Python web library, responsible for who-knows-how-many requests per second in Instagram. A project that won the ACM award (and well deserved, at that).

However, popularity is not everything. This is not a good idea.

When exposing class inheritance as a public interface, that means committing to a level of backwards compatibility that is unheard of. Even adding private methods or attributes becomes dangerous.

Let's give a toy example:

class Writer:

    _write = lambda x: None

    def set_output(self, output):
        self._write = output.write

    def write(self, message):
        formatted = self.format(message)
        self._write(message)

    def format(self, message):
        raise NotImplementedError("format")

This is a simple writer, that, while initially sending everything down a black hole, can be set to write the output to a file-like object. It needs to format the messages, so the proper usage is to subclass and override format (while taking care not to define methods called set_output or _write.)

class BufferWriter(MultiWriter):

    _buffer = False

    def format(self, message):
        if self._buffer:
            return 'Buffer: ' + message
        else:
            return 'Message: ' + message

    def switch_buffer(self):
        self._buffer = not self._buffer

The simplest formatting would return the message as is. However, this formatter is slightly less trivial -- it prefixes the message with the word Buffer or Message, depending on an internal variable that can be switched.

Now we can do things like:

>>> bp = BufferWriter()
>>> bp.set_output(sys.stdout)
>>> bp.write("hello")
Message: hello
>>> bp.switch_buffer()
>>> bp.write("hello")
Buffer: hello

This looks good, so far. Of course, things are never so simple in real life. The writer library, naturally, gets thousands of stars on GitHub. It becomes popular. There's a development community, complete with a discord channel and a mailing list. So naturally, important features get added.

class Writer:

    _buffer = ""

    _write = lambda x: None

    def set_output(self, output):
        self._write = output.write

    def write(self, message):
        self._buffer += self.format(message)
        if len(self._buffer) > 10:
            self._write(self._buffer)
            self._buffer = ""

    def format(self, message):
        raise NotImplementedError("format")

Turns out people needed to buffer some of the shorter messages. This was a crucial performance improvement, that all users were clamoring for, so version 2018.6.1 is highly anticipated.

It breaks, though, the BufferWriter. The symptoms are weird: TypeError s and other such fun. All because both the superclass and the subclass are competing to access self._buffer.

With enough care, these problems can be avoided. A library which exposes classes for inheritance must add all new private methods or attributes as __ and, naturally, never ever add any public methods or attributes. Sadly, nobody does that.

So what's the alternative?

from zope import interface

class IFormatter(interface.Interface):

    def format(message):
        """show stuff"""

We define an abstract interface. This interface [1] has only one method -- format.

@attr.s
class Writer:

    _buffer = ""

    _write = lambda x: None

    _formatter = attr.ib()

    def set_output(self, output):
        self._write = output.write

    def write(self, message):
        self._buffer += self._formatter.format(message)
        if len(self._buffer) > 10:
            self._write(self._buffer)
            self._buffer = ""

We use the attrs library [#] to define our main functionality: a class that wraps other objects, which we expect to be IFormatter.

We can automatically verify, by instead having the _formatter line say:

_formatter = attr.ib(validator=lambda instance, attribute, value:
                               verify.verifyObject(IFormatter, value))

Note that this separates the concerns: the "fake method" format has moved to a "fake class" (an interface).

@interface.implementer(IFormatter)
class BufferFormatter:

    _buffer = False

    def format(self, message):
        if self._buffer:
            return 'All Channels: ' + message
        else:
            return 'Limited Channels: ' + message

    def switch_buffer(self):
        self._buffer = not self._buffer

Note that now, if we only have the Writer object, there is no way to switch prefixes. Correctly switching prefixes means keeping access to the original object.

If there is a need to "call back" to the original methods, the original object can be passed in to the wrapped object. One advantage is that, being a distinct object, it is obvious one should only call into public methods and only access public variables.

Passing ourselves to a method is, in general, not an ideal practice. What we really should do, is to pass specific methods or variables directly into the method. But this is funny: when using inheritance, we always effectively pass ourselves to every method. So even this refactoring is a net improvement. When the biggest criticism of a refactoring is "this could now be improved even more", it usually means it is a good idea.

Credits:

• Thanks to Tom Goren for his feedback -- the original version was more aggressive.
• Thanks to Glyph Lefkowitz for pushing me to make the example better.
• Thanks to Augie Fackler and Nathaniel Manista for much of the inspiration.

You want to work 40 hours a week, you want to head home at 5PM, but—there’s this bug. And you’re stuck, and you really need to fix it, and you’re in the middle so you work just a little longer. Next thing you know you’re leaving work at 6PM.

And before long you’re working 50 hours a week, and then 60 hours a week, and if you stop working overtime it’ll hit your output, and then your manager will have a talk with you but how you really need to put in more effort. So now you’re burning out, and you’re not sure what you can do about it.

But what if you were more productive?

What if you knew how to get your work done on company time, and could spent your own time on whatever you wanted?

You can—with a little time management.

Some caveats

Before we get to the actual techniques you’ll be using, some preliminaries.

First, these techniques will only work if you have a manager who judges you based on results, not hours in the office. Keep in mind that there are many managers who claim they want a 50-hour workweek, but in practice will be happy if you do a good job in just 40. I’m also assuming your company is not in constant crisis mode. If these assumptions are wrong, better time management won’t help: it’s time to find another job.

Second, these techniques are here to help you in day-to-day time management. If production is down, you may need to work longer hours. (And again, if production is down every week, it’s time to find another job.)

Finally, for simplicity’s sake I’m assuming you get in at 9:00AM and want to leave at 5:PM. Adjust the times below accordingly if you start later in the day.

Taking control over your time

Since your problem is time creep, the solution is hard limits on when you can start new work—together with time allocated to planning so future work is more productive.

Here’s the short version of a schedule that will help you do more in less time:

1. When you get in to work you read your checkpoint from the previous workday (I’ll explain this in a bit).
2. Until 3:30PM you work as you normally would.
3. After 3:30PM you continue on any existing task you’re already working on. If you finish that task you can start new tasks only if you know they will take 15 minutes or less. If you don’t have any suitable tasks you should spend this time planning future work.
4. At 4:45PM you stop what you’re doing and checkpoint your work.
5. At 5:00PM you go home.

Let’s delve deeper so you can understand what to do, and why this will help you.

End of day → start of next day: checkpointing

In the last 15 minutes of your day you stop working and checkpoint your work. That is, you write down everything you need to know to get started quickly the next morning when you come to work.

If you’re in the middle of a task, for example, you can check in “XXX” comments into your code with notes on the next changes you were planning to make. If you’re doing planning, you can assign yourself a task and write down as much as possible about how you should implement it.

This has two benefits:

1. Next morning when you get to work, and even more so after a weekend or vacation, you’ll spend much less time context swapping and trying to remember where you were. Instead, you’ll have clear notes about what to do next.
2. By planning your work for the next day, you’re setting up your brain to work out the problem in the background, while you’re enjoying your free time. You’re more likely to wake up in the morning with a solution to a hard problem, or have an insight in the shower. For more about this see Rich Hickey’s talk on Hammock Driven-Development.

No new large tasks after 3:30PM

By the time the afternoon rolls by you’ve been working for quite a few hours, and your brain isn’t going to work as well. If you’re in the middle of a task you can keep working on it, but if you finish a task you should stop taking on large new tasks near the end of the day. You’ll do much better starting them the next day, when you’re less tired and have a longer stretch of time to work on them.

How should you spend your time? You can focus on small tasks, like code reviews.

Even more importantly, you can spend your afternoon doing planning:

• Take vague tasks and write down the details and sub-tasks.
• Investigate potential solutions.
• Research new technologies.
• Try to understand the underlying causes of problems you’re seeing come up again and again.
• Think about the big picture of what you’re working on.

In the long run planning will make your implementation work faster. And by limiting planning to only part of your day you’re making sure you don’t spend all of your time planning.

Going home at 5:00PM exactly

There’s nothing inherently wrong with spending a few more minutes finishing something past 5:00PM. The problem is that you’re experiencing hour creep—it’s a problem for you specifically. Having a hard and fast rule about when you leave will force you not to stay until 6:00 or 7:00PM.

Plus, sometimes it’s not just a few minutes, sometimes you’ll need more than that to solve the problem. And a task that will take two hours in the evening might take you only 10 minutes in the morning, when you’re well-rested.

In the long run you’ll be more productive by not working long hours.

A recap

Here’s a recap of how you should be spending your day at work:

• 9:00AM-3:30PM: Start by reading your checkpoint notes from the day before so you can get started immediately, then work normally.
• 3:30PM-4:45PM: Continue on existing task, if you’re finished then transition to small tasks and planning.
• 4:45PM-5:00PM: Checkpoint your work, then leave your office.
• 5:00PM-…: Whatever you want to do.

There’s nothing magic about this particular set of rules, of course. You will likely want change or customize this plan to your own needs and situation.

Nonetheless, since you are suffering from hour creep I suggest following this particular plan for a couple of weeks just so you start getting a sense of the benefits. Once you’ve taken control over your time you can start modifying the rules to suit your needs better.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

You probably already know what “unit testing” means. So do I.

But—what if our definitions are different? Does unit testing mean:

• Testing a self-contained unit of code with only in-memory objects involved.
• Or, does it mean automated testing?

I’ve seen both definitions used quite broadly. For example, the Python standard library has a unittest module intended for generic automated testing.

So we have two different definitions of unit testing: which one is correct?

Not just unit testing

You could argue that your particular definition is the correct one, and that other programmers should just learn to use the right terminology. But this seems to be a broader problem that applies to other forms of testing.

There’s “functional testing”:

• It might mean black box testing of the specification of the system, as per Wikipedia.
• At an old job, in contrast, we used the term differently: testing of interactions with external systems outside the control of our own code.

Or “regression testing”:

• It might mean verifying software continues to perform correctly, again as per Wikipedia.
• But at another job it meant tests that interacted with our external API.

Why is it so hard to have a consistent meaning for testing terms?

Testing as a magic formula

Imagine you’re a web developer trying to test a HTTP-based interaction with very simple underlying logic. Your thought process might go like this:

1. “Unit testing is very important, I should unit test this code—that means I should test each function in isolation.”
2. “But, oh, it’s quite difficult to test each function individually… I’d have to simulate a whole web framework! Not to mention the logic is either framework logic or pretty trivial, and I really want to be testing the external HTTP interaction.”
3. “Oh, I know, I’ll just write a test that sends an HTTP request and make assertions about the HTTP response.”
4. “Hooray! I have unit tested my application.”

You go off and share what you’ve learned—and then get scolded for not doing real unit testing, for failing to use the correct magic formula. “This is not unit testing! Where are your mocks? Why are you running a whole web server?”

The problem here is that the belief that one particular kind of testing is a magic formula for software quality. “Unit testing is the answer!” “The testing pyramid must be followed!”

When a particular formula proves not quite relevant to our particular project, our practical side kicks in and we tweak the formula until it actually does what we need. The terminology stays the same, however, even as the technique changes. But of course whether or not it’s Authentic Unit Testing™ is irrelevant: what really matters is whether it’s useful testing.

A better terminology

There is no universal criteria for code quality; it can only be judged in the context of a particular project’s goals. Rather than starting with your favorite testing technique, your starting point should be your goals. You can then use your goals to determine, and explain, what kind of testing you need.

For example, imagine you are trying to implement realistic looking ocean waves for a video game. What is the goal of your testing?

“My testing should ensure the waves look real.”

How would you do that? Not with automated tests. You’re going to have to look at the rendered graphics, and then ask some other humans to look at it. If you’re going to name this form of testing you might call it “looks-good-to-a-human testing.”

Or consider that simple web application discussed above. You can call that “external HTTP contract testing.”

It’s more cumbersome than “unit testing,” “end-to-end testing,” “automated testing”, or “acceptance testing"—but so much more informative. If you told a colleague about it they would know why you were testing, and they’d have a pretty good idea of how you were doing the testing.

Next time you’re thinking or talking about testing don’t talk about "unit testing” or “end-to-end testing.” Instead, talk about your goals: what the testing is validating or verifying. Eventually you might reach the point of talking about particular testing techniques. But if you start with your goals you are much more likely both to be understood and to reach for the appropriate tools for your task.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

You’ve just started a new job and you’re not productive yet: you get stuck, you need help, you don’t know enough. You need to learn a new codebase, a new set of conventions, a new set of business problems. You might even need to learn a new programming language.

And so now you feel anxious—

Are you doing well enough?

Are you producing enough code?

How is your manager feeling about your progress?

It’s natural to make yourself feel more comfortable by working overtime. You’re showing your manager that you’re trying, at least, and by working long hours you might get a little bit more done. You don’t want to work overtime in the long run, of course, but you can worry about that in the future.

Unfortunately, working long hours is—as you might suspect—the wrong solution: at best it won’t help, and it might even make your situation worse. Let’s see why overtime isn’t helpful, and then move on to a better solution: a solution that will make you more productive and make you look good to your manager.

Long hours won’t solve your problem

Working overtime might make you feel a little better. Unfortunately it’s also a bad solution in the short run, and a big problem in the long run.

In the short run, you’re not actually going to get more done. Long hours will just tire you out, won’t help you learn any faster, and pretty much are never the solution to producing more (here’s some research if you don’t believe me). Even worse, you might end up giving your manager the wrong impression: you’re working long hours and you’re still not productive yet?

In the long run, you’re setting bad expectations about your work hours. If you have a mediocre manager, let alone a bad one, they will often expect you to keep working those long hours. You need to set boundaries from the start: “here are my work hours, I won’t work more outside of emergencies.”

There’s a better solution: focusing on your real goal, which is learning everything you need to know about your new project.

The real solution: learning with feedback

You have two core problems:

1. You need to learn a lot, and you don’t necessarily even know what you need to learn.
2. You can’t demonstrate you’re being productive to your manager the usual way, by fixing bugs or adding features.

You can solve both problems at once with the following process:

1. Every Friday, with your week’s work still fresh in your mind, write down:
   • Everything you’ve learned that week.
   • What you think you need to learn next.
2. First thing Monday morning when you get back to work, send an email to your manager with what you wrote Friday, and an additional question: “What is missing from this list? What else do I need to learn?”
3. Your manager can now provide you with feedback about additional things you need to learn.
4. When you get stuck and don’t want to ask for help just yet, take a break and go learn something on your list.

If you follow this process:

• Your manager will know you’re not slacking off.
• You’ll get feedback about your progress and what to do next.
• You’ll be better focused on learning the right things first, which will make you productive faster.

And of course, no overtime required.

Want more suggestions for getting started on your best foot? Last time I started a new programming job I created a personal checklist: all the things I should be doing on my first few days at work. If you’d like to read it, you can download it here.

It’s Friday afternoon. You just can’t write another line of code—but you’re still stuck at the office...

What if every weekend could be a 3-day weekend?

Assume MyClass._dangerous(self) is a private method. We could have implemented the same functionality without a private method as follows:

• Define a class InnerClass with the same __init__ as MyClass
• Define InnerClass.dangerous(self) with the same logic of MyClass._dangerous
• Make MyClass into a wrapper class over InnerClass, where the wrapped attribute is private.
• Proxy all necessary work into InnerClass.

This might seem onerous, but consider that now, dangerous is part of the public interface of a class, and would need to be explicitly documented as to assumptions and guarantees. This documentation would have had to have been in comments around _dangerous anyway -- in order to clarify what its assumptions are, and what invariants it is violating in MyClass -- otherwise, maintaining the code that calls _dangerous would be hard.

Of course, this documentation is almost certain to be missing. The existence of _dangerous itself implies this was an almost mechanical refactoring of similar code into a method, with the excuse of "its private" used to avoid considering the invariants and interface.

Even if the documentation did exist, now it is possible to unit-test that the documentation is correct. Furthermore, if we use best practices when we define MyClass -- in other words, avoid creating an InnerClass object in the initializer, and only creating it in an MyClass.from_parameters, we are also in a good position to unit test MyClass.

This, of course, presented the worst case: the code for _dangerous touches absolutely every data member of MyClass. In real life, the worst case is not often encountered. When we look at a private method as a code smell, and contemplate the best way to refactor it away, it turns out that we often can find a coherent set of attributes that really does make sense as InnerClass on their own merits.

Credit: This is based on an off-handed comment Glyph made in his blog post about attrs. I am also grateful to him for reviewing a draft copy of this post, and making many useful suggestions. All mistakes in interpretation or explanation are mine alone.