I remember when I was in school; we got a difficult programming assignment that I struggled with. The algorithm, if I remember correctly, was to fill an oddly shaped virtual swimming pool at different levels, and then calculate the volume of water. The bottom of the pool was wavy curves.
The most natural way to write the code to simulate adding little bits of water at a time to the pool was with recursion. No doubt, you could unroll that into a loop and maybe a stack or two, but we were supposed to use recursion; it was the key to the assignment.
I had never encountered recursion before, and I found it mystifying. A function calls itself? That just seemed rather odd and crazy. Totally non-intuitive. I coded it up, but it never really worked properly. I got poor marks on that assignment.
Many months later, the light went on. It came out of nowhere, and suddenly, not only did recursion make sense, but it also seemed trivial. Over the decades, I’ve crafted some pretty intense recursive algorithms for all sorts of complex problems. It now comes intuitively, and I find it far easier to express the answer recursively than to unroll it.
Recursion is, I think, a simple version of what Douglas Hofstadter refers to in GEB as a ‘strange loop’; a paradox is a more advanced variety. For me, it is a conceptual understanding that sorts of acts like a cliff. When you are at the bottom, it makes no sense; it seems like a wall, but if you manage to climb up, it becomes obvious.
There are all sorts of strange loops in programming. Problems where the obvious first try is guaranteed to fail, yet there is another simpler way to encode the logic that always works.
A good example is parsing. The world is littered with what I call string-split parsers. They are the most intuitive way to decompose some complex data. You just start chopping the data into pieces, then you look at those pieces and react. For very simple data that works fine, but if you fall into programming languages, or pretty much anywhere where there are some inherent ambiguities, it will fail miserably.
But all you really need to do to climb this cliff is read the Green Dragon book. It gives you all of the practical knowledge you need to implement a parser, but also to understand any of the complicated parser generators, like Antlr or Yacc.
I guess the cool part is that once you have encountered and conquered a particular strange loop, that knowledge is so fundamental that it transcends tech stacks. If you can write a solid parser in C, you can write it in any language. If you understand how to write parsers, you can learn any programming language way faster. And nothing about that knowledge will radically change over the course of your career. You’ll jump around from different domains and stacks, but you always find that the same strange loops are waiting underneath.
A slight change over the decades was that more and more of the systems programming aspects of building software ended up in libraries or components. While that means that you’ll have fewer opportunities to implement strange loops yourself for actual production systems, you really still do need to understand how they work inside the components to leverage them properly. Being able to pound out a parser and an AST does help you understand some of the weirdness of SQL, for example. You intuitively get what a query plan is, and with a bit of understanding of relational algebra and indexing, how it is applied to the tables to satisfy your request. You’ll probably never have enough time in your life to write your own full database, but at least now you can leverage existing ones really well.
I’m not sure it’s technically a strange loop, but there is a group of mathematical solutions that I’ve often encountered that I refer to as ‘basis swaps’ that are similar. Essentially, you have a problem with respect to one basis, but in order to solve it, you need to find an isomorphism to some other basis, swap it, partially solve it there, then swap all or part of it back to the original basis. This happens in linear programming, exponential curve fitting, and it seemed to be the basis of Andrew Wiles solution for Fermat’s last theorem. But I’ve also played around with this for purely technical formal systems, such as device-independent document rendering. I guess ASTs and cross-compilers are there too, as are language-specific VMs like the JVM.
What I’ve seen in practice is that some programmers, when confronted with strange-loop type problems, go looking for shortcuts instead of diving in and trying to understand the actual problem. I do understand this. There is so much to learn in basic software development that you really don’t want to have to keep going off and reading huge textbooks. But I also know that trying to cheat a solution to a strange loop is a massive time waste. You’re always just another bug away from making it work correctly, but it will never work correctly. The best choice if you don’t have the time to do it properly is always not to do it. Instead, find someone else who knows or use something else where it already exists and is of pretty decent quality.
Mostly, there are very few strange loops in most applications programming, although there are knowledge swamps like schema normalization that cause similar grief. Once you stumble into system programming, even if it is just a simple cache, a wee bit of locking, or the necessity of transactional integrity, you run into all sorts of sticky problems that really do require existing knowledge to resolve them permanently.
Strange loops are worth learning. They don’t change with the trends or stacks, and they’ll enable you to be able to write, use, or leverage any of the software components or tools floating around out there. Sure, they slow you down a bit when you first encounter them, but if you bother to jump those hurdles, you’re lightning fast when you get older.
Thursday, April 16, 2026
Thursday, April 9, 2026
The Quality Bars
For any given software development, there are a bunch of ‘bars’ that you have to jump over, which relate to quality.
At the bottom, there is a minimum quality bar. If the code behaves worse than this, the project will be immediately cancelled. Someone who is watching the money will write the whole thing off as incompetence. To survive, you need to do better.
A little higher is the acceptable quality bar. That is where both management and the users may not be happy about the quality, but the project will definitely keep going. It may face increased scrutiny, and there will probably be lots of drama.
Above that is the reasonable quality bar. The code does what it needs to, in the way people expect it to behave. There are bugs, of course, but none of them are particularly embarrassing. Most of them exist for a short time, then are corrected. The total number of the known long-term outstanding ones is one or two digits. There are probably several places in the code where people think “we should have ...”
Then we get into the good quality bar. Bugs are rare; there are very few regrets. People like using the code; it will stay around for a long, long time. Its weakness isn’t what’s already there; it is making sure future changes don’t negate that value.
There is a great quality bar too. The code is solid, dependable, and can be used as a backbone for all sorts of other stuff. It’s crafted with a level of sophistication that keeps making it useful even for surprising circumstances. People can browse the code and get an immediate sense of what it does and why it works so well.
Above that, there is an excellent quality bar, where the code literally has no known defects. It was meticulously crafted for a very clear purpose and is nearly guaranteed to do exactly that, and nothing but that. It’s the type of code that lives can depend on.
There is a theoretical ‘perfect’ quality bar, too, but it is unreachable. It’s asymptotic.
Getting to the next bar is usually at least 10x more work than getting to that lower bar; the scale is clearly exponential. If it costs 1 just to get to minimum, then it’s 10 for acceptable, and 100 for reasonable. Roughly. This occurs because the higher bars need people to continually revisit and review the effort and aggressively refactor it, over and over again. Code that you splat out in a few hours is usually just minimum quality. Maybe if you’ve written the same thing a few times already, you can start at a higher bar, but that’s unreliable. To get up to those really high bars means having more than one author; it has to be a group of people with an intense focus, all working in sync with up-to-date collective knowledge. Excellent code has a guarantee that it will not deviate from expectations, one that you can rely on, so it’s far more than just a few lines of code.
A great deal of the code out there in libraries and frameworks falls far short of being reasonable. You might not get affected by that, as it’s often code that is sitting idle in little-used features. Still, you have to see them as a landmine waiting to go off when someone tries to push the boundaries of its usage. Code that has been battle tested for decades can generally get near the good bar, but there is always a chance that some future version will fall way, way back.
The overall quality of a codebase is really its lowest bar. So if someone splats some junk into an excellent project, if it’s ever triggered, it can pull down everything else below acceptable. This is the Achilles heel of plugins, as a few poor ones getting popular can cause a lot of damage to perceived quality.
At the bottom, there is a minimum quality bar. If the code behaves worse than this, the project will be immediately cancelled. Someone who is watching the money will write the whole thing off as incompetence. To survive, you need to do better.
A little higher is the acceptable quality bar. That is where both management and the users may not be happy about the quality, but the project will definitely keep going. It may face increased scrutiny, and there will probably be lots of drama.
Above that is the reasonable quality bar. The code does what it needs to, in the way people expect it to behave. There are bugs, of course, but none of them are particularly embarrassing. Most of them exist for a short time, then are corrected. The total number of the known long-term outstanding ones is one or two digits. There are probably several places in the code where people think “we should have ...”
Then we get into the good quality bar. Bugs are rare; there are very few regrets. People like using the code; it will stay around for a long, long time. Its weakness isn’t what’s already there; it is making sure future changes don’t negate that value.
There is a great quality bar too. The code is solid, dependable, and can be used as a backbone for all sorts of other stuff. It’s crafted with a level of sophistication that keeps making it useful even for surprising circumstances. People can browse the code and get an immediate sense of what it does and why it works so well.
Above that, there is an excellent quality bar, where the code literally has no known defects. It was meticulously crafted for a very clear purpose and is nearly guaranteed to do exactly that, and nothing but that. It’s the type of code that lives can depend on.
There is a theoretical ‘perfect’ quality bar, too, but it is unreachable. It’s asymptotic.
Getting to the next bar is usually at least 10x more work than getting to that lower bar; the scale is clearly exponential. If it costs 1 just to get to minimum, then it’s 10 for acceptable, and 100 for reasonable. Roughly. This occurs because the higher bars need people to continually revisit and review the effort and aggressively refactor it, over and over again. Code that you splat out in a few hours is usually just minimum quality. Maybe if you’ve written the same thing a few times already, you can start at a higher bar, but that’s unreliable. To get up to those really high bars means having more than one author; it has to be a group of people with an intense focus, all working in sync with up-to-date collective knowledge. Excellent code has a guarantee that it will not deviate from expectations, one that you can rely on, so it’s far more than just a few lines of code.
A great deal of the code out there in libraries and frameworks falls far short of being reasonable. You might not get affected by that, as it’s often code that is sitting idle in little-used features. Still, you have to see them as a landmine waiting to go off when someone tries to push the boundaries of its usage. Code that has been battle tested for decades can generally get near the good bar, but there is always a chance that some future version will fall way, way back.
The overall quality of a codebase is really its lowest bar. So if someone splats some junk into an excellent project, if it’s ever triggered, it can pull down everything else below acceptable. This is the Achilles heel of plugins, as a few poor ones getting popular can cause a lot of damage to perceived quality.
Thursday, April 2, 2026
Outlines
A software system is a finite resource.
For some people, this might be a surprising statement. They might feel that, as they can store a massive amount of data and talk to any other system in the world, this feels a lot more infinite.
At any given time, there is a specific quantity of hardware, wires, and electricity. If more of these resources are available than are currently being consumed, they are still finite. It’s space to grow, but still limited.
Anything that operates within this finite boundary is in itself finite. Sure, it is always changing, usually growing, but despite its massive and somewhat unimaginable size, it is still finite.
If, even in its immense size and complexity, all software is finite, then any one given system within this is also finite.
A software system has fixed boundaries. It does exactly one set of things. Parts of the code may be dynamic, so they have huge expressive capabilities, but there are still very fixed boundaries on exactly how large those are. It may be permutations greater than all of the particles in the known universe, but it still has a limit.
Time might appear to change that, but the period of time for which any given piece of software will be able to run is also finite. Someday it will come to an end. The hardware will disintegrate, the sun may supernova, or humanity may just blow itself up. More likely, though, that it will just get upgraded and essentially become something else.
Given all of this, any given software system in existence, or as imagined, has a very sharp boundary that defines it. In that sense, since it is composed of code and configurations, those precisely dictate what it can and cannot do.
You can go outside of this boundary and write tests that confirm 100% of these lines. It’s just that, given the ability to have dynamic code, it may take far, far longer to precisely test those behaviours than the lifetime of the system itself. Still, even though it is vague, due to time and complexity, the tests form an encapsulating boundary on the outside of the system.
The same is true for specifications. You could precisely specify any and all behaviours within the software system, but to get it entirely precise, the specifications would have to have a direct one-to-one correspondence with the lines of code and configurations. That would effectively make the specifications an Nth generation language that is directly compilable into a 3rd-generation one, or even lower. Because of this, some people equate precise specifications to the code itself, seeing the code as just a specification for the runtime instances of the software.
An exact specification is almost a proof of correctness. I suspect that proofs need a bit more in that they are driven by the larger context of the expectations. They are also generally only applied to algorithms, not the system as a whole.
So, all of this gives us a bunch of different ways to draw the outlines of a system.
On top of this, there are plenty of vague ways to draw or imagine them as well. We have requirements and user stories, as popular means. As well, one could perceive the system by its dual, which is the arrangement and flow of its data. You can more easily describe an inventory system, for example, by the data it holds, the way that data is interacted with, and how it flows from and to other systems. While the dual in this case is more abstract, it is also considerably simpler than specifying the functionality or the code.
Another way is to see the system by how people interact with it, essentially as a set of features that people use to solve their problems. If those features are effectively normalized, it too is a simpler representation, but if they have instead been arbitrarily evolved over years of releases, they probably have become convoluted.
One key point with all of these different outline types is that some are much better at describing certain parts of the expectations for the behaviour than others. You might need a proof of correctness for some tiny critical parts, but a rather vague outline is suitable for everything else.
No one representation fits everything perfectly, which even applies to the code. If the code was constructed over a long period of time, by people without strong habits for keeping it organized, it too has degenerated into spaghetti, and isn’t easily relatable to the other outlines. People may have changed their expectations and grown accustomed to the behaviours, but that still doesn’t make it the best possible representation for what they needed.
In practice, the best choice is often to half-do a bunch of different types of outlines, then set it all running and repair the obvious deficiencies. While this obviously doesn’t ensure high quality or rigorous mapping to the expectations, it is likely the cheapest form of creating complex software systems. It’s just that it is also extremely high-risk and prone to failure.
For some people, this might be a surprising statement. They might feel that, as they can store a massive amount of data and talk to any other system in the world, this feels a lot more infinite.
At any given time, there is a specific quantity of hardware, wires, and electricity. If more of these resources are available than are currently being consumed, they are still finite. It’s space to grow, but still limited.
Anything that operates within this finite boundary is in itself finite. Sure, it is always changing, usually growing, but despite its massive and somewhat unimaginable size, it is still finite.
If, even in its immense size and complexity, all software is finite, then any one given system within this is also finite.
A software system has fixed boundaries. It does exactly one set of things. Parts of the code may be dynamic, so they have huge expressive capabilities, but there are still very fixed boundaries on exactly how large those are. It may be permutations greater than all of the particles in the known universe, but it still has a limit.
Time might appear to change that, but the period of time for which any given piece of software will be able to run is also finite. Someday it will come to an end. The hardware will disintegrate, the sun may supernova, or humanity may just blow itself up. More likely, though, that it will just get upgraded and essentially become something else.
Given all of this, any given software system in existence, or as imagined, has a very sharp boundary that defines it. In that sense, since it is composed of code and configurations, those precisely dictate what it can and cannot do.
You can go outside of this boundary and write tests that confirm 100% of these lines. It’s just that, given the ability to have dynamic code, it may take far, far longer to precisely test those behaviours than the lifetime of the system itself. Still, even though it is vague, due to time and complexity, the tests form an encapsulating boundary on the outside of the system.
The same is true for specifications. You could precisely specify any and all behaviours within the software system, but to get it entirely precise, the specifications would have to have a direct one-to-one correspondence with the lines of code and configurations. That would effectively make the specifications an Nth generation language that is directly compilable into a 3rd-generation one, or even lower. Because of this, some people equate precise specifications to the code itself, seeing the code as just a specification for the runtime instances of the software.
An exact specification is almost a proof of correctness. I suspect that proofs need a bit more in that they are driven by the larger context of the expectations. They are also generally only applied to algorithms, not the system as a whole.
So, all of this gives us a bunch of different ways to draw the outlines of a system.
On top of this, there are plenty of vague ways to draw or imagine them as well. We have requirements and user stories, as popular means. As well, one could perceive the system by its dual, which is the arrangement and flow of its data. You can more easily describe an inventory system, for example, by the data it holds, the way that data is interacted with, and how it flows from and to other systems. While the dual in this case is more abstract, it is also considerably simpler than specifying the functionality or the code.
Another way is to see the system by how people interact with it, essentially as a set of features that people use to solve their problems. If those features are effectively normalized, it too is a simpler representation, but if they have instead been arbitrarily evolved over years of releases, they probably have become convoluted.
One key point with all of these different outline types is that some are much better at describing certain parts of the expectations for the behaviour than others. You might need a proof of correctness for some tiny critical parts, but a rather vague outline is suitable for everything else.
No one representation fits everything perfectly, which even applies to the code. If the code was constructed over a long period of time, by people without strong habits for keeping it organized, it too has degenerated into spaghetti, and isn’t easily relatable to the other outlines. People may have changed their expectations and grown accustomed to the behaviours, but that still doesn’t make it the best possible representation for what they needed.
In practice, the best choice is often to half-do a bunch of different types of outlines, then set it all running and repair the obvious deficiencies. While this obviously doesn’t ensure high quality or rigorous mapping to the expectations, it is likely the cheapest form of creating complex software systems. It’s just that it is also extremely high-risk and prone to failure.
Thursday, March 26, 2026
Cogtastic
Since I started programming decades ago, there has been one seriously annoying trend that just does not seem to want to go away.
If you work for an enterprise, banging away at their internal systems, the management above you really, really, really wants you to just sit there, do your job, and not cause any problems. They want you to be an obedient little cog. Just a part of the machine that they direct to satisfy their goals.
The utter failure with that is that you are in the trenches. And to build even halfway decent stuff, you have to understand a huge amount about the technology and the domain. If you mix in some empathy for the actual users, then the results are usually pretty good. You’ve solved real problems for real people, and they are usually thankful.
But the managers sitting way up high on the hill are disconnected from all of that. They don’t care about users or technology; they care about budgets, politics, and promotions. That’s not a surprise; that is the world they are forced to live in.
But it is a fly in the ointment, since their games are entirely disconnected from the users' lives. And you’re caught in the middle.
In the best circumstances, management enables you to find an appropriate balance between all sides and still keep mostly to some crazy artificial schedule. They trust you, and they listen to your concerns. You’re not a cog, you’re a critical part of the construction process.
But there are very few higher-up managers who actually subscribe to that perspective. Most, instead, believe that they were anointed as the boss and that their will supercedes all other concerns. These are the people who want you to be a quiet, obedient cog. “Just shut up and do your job.”
From my direct experience, it has always been a disaster. It was what was failing in the 70s, 80s, 90s, and early turn of the century with software development. It wasn’t “Waterfall” that deviated the work from where it needed to be; it was the people in charge who mindlessly went off in the wrong direction. If they had been paying attention, they would be course correcting as needed, following whatever chaotic changes tumbled out of the fray. In those days when things failed, they failed at the top, but somehow it was the weight of the process that got blamed.
From where I have often sat, the “root problem” has and will always be a lack of understanding. The people driving and working on the development project get disconnected from the people who will ultimately use the output. If you don’t know what the user’s problem really is, how can you build any type of solution that will help them? You have to dig into that; it’s not optional.
The desire for the development teams to just be mindless cogs comes directly from that cogtastic viewpoint. There is some type of made-up schedule, but the programmers keep surfacing ignored or forgotten issues. If management indulges, then the schedule gets blown. Instead of blaming analysis or a lack of understanding, it is just easier to suppress the feedback and keep on going as planned, hoping that some good luck happens somewhere along the way.
I’m sure there are lots of examples out there of out-of-control projects getting saved at the last minute by some Wesley who manages to Save the Ship and thus avoid impending disaster. That’s great, but highly unreliable, and the people who do this never get any of the credit they deserve for avoiding the original doomed fate. It’s only when they are gone that people realize that they were quietly avoiding the cliffs, while staying nearly on course.
So, you get this situation where someone is “in charge,” and they want their will to be manifested as and how they decide, but they do not truly have the right objectives to achieve success.
This takes us back to AI. Instead of being some cool new tool to lift the quality of the work we're doing, it seeks to turn the developers themselves into those disconnected managers. So they generate whackloads of code which they don’t understand, and don’t care about, because they are trying to impress the higher-ups with their “velocity”. What is actually happening gets ignored, and what is really needed gets ignored, too. Now, instead of them being the cog, it is some AI agent who fills that role, and the whole cycle repeats.
The act of engineering some large complex system involves both understanding how it works and why it is necessary. Nothing can escape that. In the Waterfall days, people blamed the heavy processes, but making them super light and hugely reactive did nothing to fix the problems. Now, we’ll see the same effect play out again. The developers will just be agent managers, and the auto-cogs below them will pile up more of the wrong stuff. You still have the wrong stuff even if you get it faster, and there is a lot more of it to add to the mudball, which is worse.
The moral of the story is that people just don’t seem to be learning the same lesson that keeps rearing its ugly head over and over again. A vague notion of what you want is not enough to build it. The real work is in taking that loose idea and understanding it at a very deep level so that you can then actuate it into the large number of parts you need that all work together as expected.
The people in the middle who pull off this feat are not and will never be cogs. What’s in their heads, and what they know, is the essence of being able to pull this thing out of the ethos and into reality. Their job is to understand it all and then find a way to turn that understanding into physical bits. They are good at it if what is produced matches everyone’s expectations. The users, management, technologists, etc. There is this codebase that, when built and deployed, becomes a real solution to all of these problems. That codebase, and its boundaries as code, a specification, tests, or proofs, is just a manifestation of the software developers' actual understanding. If, in the middle of doing that, it clicks in that part of the ask is too ambiguous, way off the mark, impossible, or just crazy, it’s the developer's understanding that is the mission-critical part of success. Address that, and it probably works. Ignore that, and it definitely fails.
If you work for an enterprise, banging away at their internal systems, the management above you really, really, really wants you to just sit there, do your job, and not cause any problems. They want you to be an obedient little cog. Just a part of the machine that they direct to satisfy their goals.
The utter failure with that is that you are in the trenches. And to build even halfway decent stuff, you have to understand a huge amount about the technology and the domain. If you mix in some empathy for the actual users, then the results are usually pretty good. You’ve solved real problems for real people, and they are usually thankful.
But the managers sitting way up high on the hill are disconnected from all of that. They don’t care about users or technology; they care about budgets, politics, and promotions. That’s not a surprise; that is the world they are forced to live in.
But it is a fly in the ointment, since their games are entirely disconnected from the users' lives. And you’re caught in the middle.
In the best circumstances, management enables you to find an appropriate balance between all sides and still keep mostly to some crazy artificial schedule. They trust you, and they listen to your concerns. You’re not a cog, you’re a critical part of the construction process.
But there are very few higher-up managers who actually subscribe to that perspective. Most, instead, believe that they were anointed as the boss and that their will supercedes all other concerns. These are the people who want you to be a quiet, obedient cog. “Just shut up and do your job.”
From my direct experience, it has always been a disaster. It was what was failing in the 70s, 80s, 90s, and early turn of the century with software development. It wasn’t “Waterfall” that deviated the work from where it needed to be; it was the people in charge who mindlessly went off in the wrong direction. If they had been paying attention, they would be course correcting as needed, following whatever chaotic changes tumbled out of the fray. In those days when things failed, they failed at the top, but somehow it was the weight of the process that got blamed.
From where I have often sat, the “root problem” has and will always be a lack of understanding. The people driving and working on the development project get disconnected from the people who will ultimately use the output. If you don’t know what the user’s problem really is, how can you build any type of solution that will help them? You have to dig into that; it’s not optional.
The desire for the development teams to just be mindless cogs comes directly from that cogtastic viewpoint. There is some type of made-up schedule, but the programmers keep surfacing ignored or forgotten issues. If management indulges, then the schedule gets blown. Instead of blaming analysis or a lack of understanding, it is just easier to suppress the feedback and keep on going as planned, hoping that some good luck happens somewhere along the way.
I’m sure there are lots of examples out there of out-of-control projects getting saved at the last minute by some Wesley who manages to Save the Ship and thus avoid impending disaster. That’s great, but highly unreliable, and the people who do this never get any of the credit they deserve for avoiding the original doomed fate. It’s only when they are gone that people realize that they were quietly avoiding the cliffs, while staying nearly on course.
So, you get this situation where someone is “in charge,” and they want their will to be manifested as and how they decide, but they do not truly have the right objectives to achieve success.
This takes us back to AI. Instead of being some cool new tool to lift the quality of the work we're doing, it seeks to turn the developers themselves into those disconnected managers. So they generate whackloads of code which they don’t understand, and don’t care about, because they are trying to impress the higher-ups with their “velocity”. What is actually happening gets ignored, and what is really needed gets ignored, too. Now, instead of them being the cog, it is some AI agent who fills that role, and the whole cycle repeats.
The act of engineering some large complex system involves both understanding how it works and why it is necessary. Nothing can escape that. In the Waterfall days, people blamed the heavy processes, but making them super light and hugely reactive did nothing to fix the problems. Now, we’ll see the same effect play out again. The developers will just be agent managers, and the auto-cogs below them will pile up more of the wrong stuff. You still have the wrong stuff even if you get it faster, and there is a lot more of it to add to the mudball, which is worse.
The moral of the story is that people just don’t seem to be learning the same lesson that keeps rearing its ugly head over and over again. A vague notion of what you want is not enough to build it. The real work is in taking that loose idea and understanding it at a very deep level so that you can then actuate it into the large number of parts you need that all work together as expected.
The people in the middle who pull off this feat are not and will never be cogs. What’s in their heads, and what they know, is the essence of being able to pull this thing out of the ethos and into reality. Their job is to understand it all and then find a way to turn that understanding into physical bits. They are good at it if what is produced matches everyone’s expectations. The users, management, technologists, etc. There is this codebase that, when built and deployed, becomes a real solution to all of these problems. That codebase, and its boundaries as code, a specification, tests, or proofs, is just a manifestation of the software developers' actual understanding. If, in the middle of doing that, it clicks in that part of the ask is too ambiguous, way off the mark, impossible, or just crazy, it’s the developer's understanding that is the mission-critical part of success. Address that, and it probably works. Ignore that, and it definitely fails.
Thursday, March 19, 2026
Interviews
I was crafted by the Waterloo co-op program in the late eighties. Part of that experience was a crazy large number of interviews, so I got pretty good at them. Since then, I’ve worked for over a dozen companies.
For one interview (for my all-time favourite job), I was really young, so I got asked rapid tech questions and had to bring printouts of my older code with me. That was fine, it was a systems programming job and really competitive, lots of people desired it.
For another interview, at the turn of the century, I just went for dinner and drinks. Definitely my favourite interview.
I’ve had a couple of interviews in coffee shops; they were usually successful. The casual atmosphere really helps to connect.
Once I got ganged up on. I think it was six of them crammed into a little office, but the questions were product, process, and feature-related, not coding, so it was fine.
Often, I was at the interview because a friend I had worked with in the past was trying to pull me in. That generally made them go pretty easy on me.
I’ve had some bad interviews, though. Usually, when applying for advertised jobs.
Once I showed up, they put me in a big room with a bunch of other people and gave us a written test. I took it, sat down, and just signed my name. Then I got up, handed it in and left. No way I was going to work for them.
Another time, I was grilled on tech that I told them I hadn’t used for twenty years. The kid interviewing me was annoyed that I couldn’t remember some esoterica. Seriously?
One time, they gave me an online coding test. An editor embedded in an online chat. The first question was okay, but for the second question, they wanted me to correctly code something huge. I explained the actual theory behind it and why it wasn’t trivial, but they didn’t understand and told me just to grind it out in a little bit of ‘approximate’ code. I hemmed and hawed for a while, then said I wasn’t going to finish. They told me to try anyway, so I sat there quietly until the interview timed out. I was hoping awkward silence made my point.
After one interview, one of the executives proudly told me that I would have to look after his “hobby” system. I turned that down without a second thought.
For another, it was going well, but then I started making jokes about live locks. Turns out the interviewer did his master's thesis on that topic. Opps.
One time, they said my take-home coding test had too many functions. I just laughed.
Another time, the interviewer started in with tricky little puzzle questions. I had seen them all before, so I could have answered, but I was already having a bad day, so I blew up. I got really angry, and the interviewer tried to calm me down. We agreed to meet in person, which went really well. I was sent across the country for a round of second interviews, but I was told I had a bit too much personality for them. It was still fun, and they paid my expenses.
One time, one of my co-workers showed me the tests he was going to use for interviews. He said to find the one problem, I pointed out a whole bunch of them; he got mad at me. Lol.
I often interviewed candidates, too. If we were multiple interviewers, I’d get the others to ask the tech questions, and I’d focus on personality. I like to see that people are curious and keen to learn. If they had that and I could get them talking about something that excited them, I generally accepted them. That had a pretty good track record of finding good people.
I usually expected a long ramp-up time and the need for training, so I was rarely looking for prefab employees. I saw them as longer-term bets, which tended to pay off better.
For one company, since the code was brutal, I used a technical question that I was pretty sure the candidates couldn't answer. I just wanted them to try to work through the problem. I would help, but not give it all away. If they were stumped and started pitching ideas, it was perfect. I had some pretty good hires from that.
For that round of interviews, one of the senior candidates got insulted and said he wouldn’t take the test. I obviously sympathized, but for that type of work, it wasn’t optional; it was our daily grind.
Overall, my hiring track record is iffy. Some great hires, but also some duds. Usually, though, the duds were caused by scarcity and/or my not trusting my own instincts. Sometimes the candidates are too limited; there is not much you can do about it.
I really hate the big, long, stupid interviews, particularly when the questions are way out of whack with the actual work. Seems like an ego problem if they’ll test you on stuff that you’d never have to do. They’re trying too hard to be cool, and I really hate the taste of Kool-Aid. If the interview makes you uncomfortable, the actual job is probably worse. I never felt bad when I just walked away, but I usually wasn't desperate either. That helps.
Only once did I really have to take a job that I didn’t want. I stayed for a while, but some days were hard. The irony was that many of my later jobs were with people I had met at that early one. The job wasn’t great, but the contacts turned out to be awesome. That's why it's important to keep a positive attitude even in a negative situation.
I’ve always figured that if you got the world’s ten greatest programmers all together on a project, they would spend their days fighting with each other and nothing practical would get built. A less impressive team that works together really well is always better. It’s too bad modern interview practices don’t reflect that.
If you’re interviewing these days, be patient, stay strong. It’s a numbers game. Win a few, lose a lot.
For one interview (for my all-time favourite job), I was really young, so I got asked rapid tech questions and had to bring printouts of my older code with me. That was fine, it was a systems programming job and really competitive, lots of people desired it.
For another interview, at the turn of the century, I just went for dinner and drinks. Definitely my favourite interview.
I’ve had a couple of interviews in coffee shops; they were usually successful. The casual atmosphere really helps to connect.
Once I got ganged up on. I think it was six of them crammed into a little office, but the questions were product, process, and feature-related, not coding, so it was fine.
Often, I was at the interview because a friend I had worked with in the past was trying to pull me in. That generally made them go pretty easy on me.
I’ve had some bad interviews, though. Usually, when applying for advertised jobs.
Once I showed up, they put me in a big room with a bunch of other people and gave us a written test. I took it, sat down, and just signed my name. Then I got up, handed it in and left. No way I was going to work for them.
Another time, I was grilled on tech that I told them I hadn’t used for twenty years. The kid interviewing me was annoyed that I couldn’t remember some esoterica. Seriously?
One time, they gave me an online coding test. An editor embedded in an online chat. The first question was okay, but for the second question, they wanted me to correctly code something huge. I explained the actual theory behind it and why it wasn’t trivial, but they didn’t understand and told me just to grind it out in a little bit of ‘approximate’ code. I hemmed and hawed for a while, then said I wasn’t going to finish. They told me to try anyway, so I sat there quietly until the interview timed out. I was hoping awkward silence made my point.
After one interview, one of the executives proudly told me that I would have to look after his “hobby” system. I turned that down without a second thought.
For another, it was going well, but then I started making jokes about live locks. Turns out the interviewer did his master's thesis on that topic. Opps.
One time, they said my take-home coding test had too many functions. I just laughed.
Another time, the interviewer started in with tricky little puzzle questions. I had seen them all before, so I could have answered, but I was already having a bad day, so I blew up. I got really angry, and the interviewer tried to calm me down. We agreed to meet in person, which went really well. I was sent across the country for a round of second interviews, but I was told I had a bit too much personality for them. It was still fun, and they paid my expenses.
One time, one of my co-workers showed me the tests he was going to use for interviews. He said to find the one problem, I pointed out a whole bunch of them; he got mad at me. Lol.
I often interviewed candidates, too. If we were multiple interviewers, I’d get the others to ask the tech questions, and I’d focus on personality. I like to see that people are curious and keen to learn. If they had that and I could get them talking about something that excited them, I generally accepted them. That had a pretty good track record of finding good people.
I usually expected a long ramp-up time and the need for training, so I was rarely looking for prefab employees. I saw them as longer-term bets, which tended to pay off better.
For one company, since the code was brutal, I used a technical question that I was pretty sure the candidates couldn't answer. I just wanted them to try to work through the problem. I would help, but not give it all away. If they were stumped and started pitching ideas, it was perfect. I had some pretty good hires from that.
For that round of interviews, one of the senior candidates got insulted and said he wouldn’t take the test. I obviously sympathized, but for that type of work, it wasn’t optional; it was our daily grind.
Overall, my hiring track record is iffy. Some great hires, but also some duds. Usually, though, the duds were caused by scarcity and/or my not trusting my own instincts. Sometimes the candidates are too limited; there is not much you can do about it.
I really hate the big, long, stupid interviews, particularly when the questions are way out of whack with the actual work. Seems like an ego problem if they’ll test you on stuff that you’d never have to do. They’re trying too hard to be cool, and I really hate the taste of Kool-Aid. If the interview makes you uncomfortable, the actual job is probably worse. I never felt bad when I just walked away, but I usually wasn't desperate either. That helps.
Only once did I really have to take a job that I didn’t want. I stayed for a while, but some days were hard. The irony was that many of my later jobs were with people I had met at that early one. The job wasn’t great, but the contacts turned out to be awesome. That's why it's important to keep a positive attitude even in a negative situation.
I’ve always figured that if you got the world’s ten greatest programmers all together on a project, they would spend their days fighting with each other and nothing practical would get built. A less impressive team that works together really well is always better. It’s too bad modern interview practices don’t reflect that.
If you’re interviewing these days, be patient, stay strong. It’s a numbers game. Win a few, lose a lot.
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