When I was really young and first started coding, I hated relational databases.
They didn’t teach us much about them in university, but they were entirely dominant in enterprise development for the 80s and 90s. If you needed persistence, only an RDBMS could be considered. Any other choice, like rolling it yourself, files, or lighter dbs, caches, was considered inappropriate. People would get mad if you used them.
My first experiences with an RDBMS were somewhat painful. The notion of declarative programming felt a bit foreign to me, and those earlier databases were cruder in their syntax.
But eventually I figured them out, and even came to appreciate all of the primary and secondary capabilities. You don’t just get reliable queries; you can use them for dynamic behaviour and distributed locking issues as well. Optimizations can be a little tiring, and you have to stay tight to normal forms to avoid piling up severe technical debt, but with practice, they are a good, strong, solid foundation. You just have to use them correctly to get the most out of them.
If you need reliable persistence (and you do) and the computations aren’t exocitc (and they mostly aren’t), then relying on a good RDBMS is generally the best choice. You just have to learn a lot about the technology and use it properly, but then it works as expected.
If you try to use it incorrectly, you are doing what I like to call “going against the grain”. It’s an ancient woodworking expression, but it is highly fitting for technology. With the grain, you are using it as the originators intended, and against the grain, you are trying to get it to do something clever, awkward, or funny.
Sometimes people think they are clever by trying to force technology to do something unexpected. But that is always a recipe for failure. Even if you could get it to work with minimal side effects, the technology evolves, so the tricks will turn ugly.
Once you’ve matured as a programmer, you realize that clever is just asking for trouble, and usually for no good reason. Most code, most of the time, is pretty basic. At least 90% of it. Usually, it only needs to do the same things that people have been doing for at least half a century. The problem isn’t coming up with some crazy, clever new approach, but rather finding a very reasonable one in an overly short period of time, in a way that you can keep moving it forward over a long series of upgrades.
We build things, but they are not art; they are industrial-strength machinery. They need to be clean, strong, and withstand the ravages of the future. That is quality code; anything else is just a distraction.
Now, if you are pushing the state of the art for some reason, then you would have to go outside of the standard components and their usages. So, I wasn’t surprised that NoSQL came into existence, and I have had a few occasions where I both needed it and really appreciated it. ORMS are similar.
It’s just that I would not have been able to leverage these technologies properly if I didn’t already understand how to get the most out of an RDBMS. I needed to hit the limits first to gain an understanding.
So, when I saw a lot of people using NoSQL to skip learning about RDBMSes, I knew right away that it was a tragic mistake. They failed to understand that their usage was rather stock and just wanted to add cool new technologies to their resumes. That is the absolute worst reason to use any technology, ever. Or as I like to say, experiment on your own time, take your day job seriously.
In that sense, using an RDBMS for something weird is going against the grain, but skipping it for some other eclectic technology is also going against the grain. Two variations on the same problem. If you need to build something that is reliable, then you have to learn what reliable means and use that to make stronger decisions about which components to pile into the foundations. Maybe the best choice is old, and not great for your resume, but that is fine. Doing a good job is always more important.
This applies, of course, to all technologies, not just RDBMSes. My first instinct is to minimize using any external components, but if I have to, then I am looking for the good, reliable, industrial-strength options. Some super-cool, trendy, new component automatically makes me suspicious. Old, crusty, battle-scarred stuff may not look as sweet, but in most cases, it is usually a lot more reliable. And the main quality that I am looking for is reliability.
But even after you decide on the tech, you still have to find the grain and go with it. You pick some reasonable library, but then try to make it jump around in unreasonable ways; it will not end well. In the worst case, you incorrectly convince yourself that it is doing something you need, but it isn’t. Swamping out a big component at the last minute before a release is always a huge failure and tends to result in really painful circumstances. A hole that big could take years to recover from.
So, it plays back to the minimization. If we have to use a component, then we have to know how to use it properly, so it isn’t that much of a time saving, unless it is doing something sophisticated enough that learning all of that from scratch is way out of the time budget. If you just toss in components for a tiny fraction of their functionality, the code degenerates into a huge chaotic mess. You lose that connection to knowing what it will really do, and that is always fatal. Mystery code is not something you ever want to support; it will just burn time, and time is always in short supply.
In general, if you have to add a component, then you want to try to use all of its core features in a way that the authors expected you to use them. And you never want to have two contradictory components in the same system; that is really bad. Use it fully, use it properly, and get the most out of the effort it took to integrate it fully. That will keep things sane. Overall, beware of any components you rely on; they will not save you time; they may just minimize some of the learning you should have done, but they are never free.
Thursday, January 8, 2026
Thursday, January 1, 2026
New Year
I was addicted from the moment I bought my first computer: a heavily used Apple ][+ clone. Computers hadn’t significantly altered our world yet, but I saw immense potential in that machine.
None of us, back in those days, could have predicted how much these machines would damage our world. We only saw the good.
And there has been lots of good; I can’t live without GPS in the car, and online shopping is often handy. I can communicate with all sorts of people I would not have been able to meet before.
None of us, back in those days, could have predicted how much these machines would damage our world. We only saw the good.
And there has been lots of good; I can’t live without GPS in the car, and online shopping is often handy. I can communicate with all sorts of people I would not have been able to meet before.
But there have also been a massive number of negative effects, from surveillance to endless lies and social divisions.
Tools are inherently neutral, so they have both good and bad uses; that is their nature. We have these incredibly powerful machines, but what have we done with them? The world is far more chaotic, way less fair, and highly polluted now. We could have used the machines to lift ourselves up, but instead we’ve let a dodgy minority use them to squeeze more money out of us. Stupid.
I’m hoping that we can turn a corner for 2026 and get back to leveraging these machines to make the world a better place. That we ignore those ambitious weasels who only care about monetizing everything and instead start to use software to really solve our rapidly growing set of nasty problems. Sure, it is not profitable, but who cares anymore? Having a lot of money while living on a burning planet isn’t really great. Less money on a happy planet is a big improvement.
The worst problem for the software industry is always trying to rush through the work, only solving redundant, trivial problems. We need to switch focus. Go slow, build up knowledge and sophistication, and ignore those people shouting at us to go faster. Good programming is slow. Slow is good. Take your time, concentrate on getting better code, and pay close attention to all of the little details. Programming is pedantic; we seem to have forgotten this.
The other thing is that we need to be far more careful about what software we write. Just say no to writing sleazy code. Not all code should exist. If they find someone else, that is not your problem, but doing questionable work because someone else might is a sad excuse. As more of us refuse, it will get a lot harder for them to achieve their goals. We can’t stop them, but at least we can slow them down a little.
The final thing to do is to forget about the twisted, messed-up history of software, at least for a moment. Think big, think grand. We have these powerhouse intellectual tools; we should be using them to lift humanity, not just for lame data entry. We need to build up stable, strong complexity that we can leverage to solve larger and larger problems. A rewrite of some crude approach with another crude approach just isn’t leveraging any of the capabilities of software. Rearranging the screens and using different widgets is only going sideways, not up. Software can remember the full context and help us make way better decisions. That is its power; we just need to start building things that truly leverage it.
Given the decreasing state of the world these days, it makes sense that we use this moment to shift focus. If computers got us into this mess, then they can also get us out of it. It’s been clear for quite a while that things are not going very well, but many of the people leveraging that sentiment are only doing so in order to make things worse. It's time we change that.
Tools are inherently neutral, so they have both good and bad uses; that is their nature. We have these incredibly powerful machines, but what have we done with them? The world is far more chaotic, way less fair, and highly polluted now. We could have used the machines to lift ourselves up, but instead we’ve let a dodgy minority use them to squeeze more money out of us. Stupid.
I’m hoping that we can turn a corner for 2026 and get back to leveraging these machines to make the world a better place. That we ignore those ambitious weasels who only care about monetizing everything and instead start to use software to really solve our rapidly growing set of nasty problems. Sure, it is not profitable, but who cares anymore? Having a lot of money while living on a burning planet isn’t really great. Less money on a happy planet is a big improvement.
The worst problem for the software industry is always trying to rush through the work, only solving redundant, trivial problems. We need to switch focus. Go slow, build up knowledge and sophistication, and ignore those people shouting at us to go faster. Good programming is slow. Slow is good. Take your time, concentrate on getting better code, and pay close attention to all of the little details. Programming is pedantic; we seem to have forgotten this.
The other thing is that we need to be far more careful about what software we write. Just say no to writing sleazy code. Not all code should exist. If they find someone else, that is not your problem, but doing questionable work because someone else might is a sad excuse. As more of us refuse, it will get a lot harder for them to achieve their goals. We can’t stop them, but at least we can slow them down a little.
The final thing to do is to forget about the twisted, messed-up history of software, at least for a moment. Think big, think grand. We have these powerhouse intellectual tools; we should be using them to lift humanity, not just for lame data entry. We need to build up stable, strong complexity that we can leverage to solve larger and larger problems. A rewrite of some crude approach with another crude approach just isn’t leveraging any of the capabilities of software. Rearranging the screens and using different widgets is only going sideways, not up. Software can remember the full context and help us make way better decisions. That is its power; we just need to start building things that truly leverage it.
Given the decreasing state of the world these days, it makes sense that we use this moment to shift focus. If computers got us into this mess, then they can also get us out of it. It’s been clear for quite a while that things are not going very well, but many of the people leveraging that sentiment are only doing so in order to make things worse. It's time we change that.
Thursday, December 18, 2025
A Manifestation of my Understanding
When I code, I only code what I know. How could it be otherwise?
If I were writing out mysterious instructions that I am clueless about, I’d never be able to tell if they did or did not do what people wanted them to do. I could blindly follow some loose specification, but the inevitable typos and inherent vagueness would force the code to drift far from what is desired. I’d have no sense of direction on how to get it back on track.
So, before I code, I learn. I learn about the tech I am using, and I learn about the problems that people need solving. I try to learn about the state of the art and the different ways other people have solved similar problems.
I take all of this learning and use it to craft the instructions. I put it out there, first in testing, and use any feedback to fix both unintentional problems and learning ones. Sometimes, I just didn't fully get all of the ramifications of some combination of the topics. Opps.
In that way, any and all of the code I lay out in editors, for the various different internal and external parts of the software that I will release, are very much manifestations of what I know, who I am, and what I believe.
Which is to say that the work is not coding, it is learning. Code is the result of that knowledge I acquired, not some arbitrary arrangement of instructions.
This is no different than writers for magazines and newspapers. They do some amount of research and investigative journalism, then they craft articles intended to communicate the things that they, too, have learned.
They might be constrained by style guides and ethical concerns to write out what they know in a certain way so that it fits in with the larger publication, but their writing is still their expression of what they know. Their personality is still imprinted on it. It might be edited quite a bit by others, which may pull it away somewhat from their original effort or focus, but ultimately, in the end, it is still mostly a manifestation of them.
People who try to disconnect code from the thinking of the programmers do so because they don’t like having to accommodate the programmers' needs. They want programmers to be mindless clerks who blindly grind out endless code. We see all sorts of movements in the software industry that express this view, but it is not and will never be the case. If you have a huge series of instructions that is intended to do something specific, then someone has to understand what those instructions are. They are too precise and pedantic for people flying at higher levels to belt out in pictures or general descriptions. To work as needed, they need that deep level of correctness to be there. You can’t skip past that, so you can’t skip past programmers, and at least you should respect them enough to understand that their works are actually manifestations of themselves.
You can’t unbind code from its authors. It just isn’t possible, until maybe AGI. If you need some complex code that does something precise, then you need some people to fully, completely, and totally understand exactly what those instructions do, and why they are correct and precise.
In that sense, everything that I coded from scratch is an extension of my personality. It is written all over the work. Maybe if I do some little hacks to someone else’s code, there is little trace of my personality there, but if it is a large, unified block of code that I wrote, not only is it me that wrote it, but if you looked at it carefully and you knew me, you’d know that I was the one who wrote it. We leave a lot of ourselves behind in our code; we have no choice in that.
I get that it is inconvenient to some management who wants to claim all of the credit for our work, but they are just self-absorbed. They can’t hide stuff from me; I have to know it all in order for the code to live up to its usefulness. I might not care why we are solving a given set of problems, but I can not do even a reasonable job if I am blindfolded. They can’t just chuck me away afterwards and think that it will all continue on as normal. Replacing me with a kid that doesn’t know anything yet is cheaper, but also grossly ineffective. It will take a long time for the kid to learn what I did over the decades I spent doing it. Then it will be their code and a manifestation of who they are, so the problem persists.
If I were writing out mysterious instructions that I am clueless about, I’d never be able to tell if they did or did not do what people wanted them to do. I could blindly follow some loose specification, but the inevitable typos and inherent vagueness would force the code to drift far from what is desired. I’d have no sense of direction on how to get it back on track.
So, before I code, I learn. I learn about the tech I am using, and I learn about the problems that people need solving. I try to learn about the state of the art and the different ways other people have solved similar problems.
I take all of this learning and use it to craft the instructions. I put it out there, first in testing, and use any feedback to fix both unintentional problems and learning ones. Sometimes, I just didn't fully get all of the ramifications of some combination of the topics. Opps.
In that way, any and all of the code I lay out in editors, for the various different internal and external parts of the software that I will release, are very much manifestations of what I know, who I am, and what I believe.
Which is to say that the work is not coding, it is learning. Code is the result of that knowledge I acquired, not some arbitrary arrangement of instructions.
This is no different than writers for magazines and newspapers. They do some amount of research and investigative journalism, then they craft articles intended to communicate the things that they, too, have learned.
They might be constrained by style guides and ethical concerns to write out what they know in a certain way so that it fits in with the larger publication, but their writing is still their expression of what they know. Their personality is still imprinted on it. It might be edited quite a bit by others, which may pull it away somewhat from their original effort or focus, but ultimately, in the end, it is still mostly a manifestation of them.
People who try to disconnect code from the thinking of the programmers do so because they don’t like having to accommodate the programmers' needs. They want programmers to be mindless clerks who blindly grind out endless code. We see all sorts of movements in the software industry that express this view, but it is not and will never be the case. If you have a huge series of instructions that is intended to do something specific, then someone has to understand what those instructions are. They are too precise and pedantic for people flying at higher levels to belt out in pictures or general descriptions. To work as needed, they need that deep level of correctness to be there. You can’t skip past that, so you can’t skip past programmers, and at least you should respect them enough to understand that their works are actually manifestations of themselves.
You can’t unbind code from its authors. It just isn’t possible, until maybe AGI. If you need some complex code that does something precise, then you need some people to fully, completely, and totally understand exactly what those instructions do, and why they are correct and precise.
In that sense, everything that I coded from scratch is an extension of my personality. It is written all over the work. Maybe if I do some little hacks to someone else’s code, there is little trace of my personality there, but if it is a large, unified block of code that I wrote, not only is it me that wrote it, but if you looked at it carefully and you knew me, you’d know that I was the one who wrote it. We leave a lot of ourselves behind in our code; we have no choice in that.
I get that it is inconvenient to some management who wants to claim all of the credit for our work, but they are just self-absorbed. They can’t hide stuff from me; I have to know it all in order for the code to live up to its usefulness. I might not care why we are solving a given set of problems, but I can not do even a reasonable job if I am blindfolded. They can’t just chuck me away afterwards and think that it will all continue on as normal. Replacing me with a kid that doesn’t know anything yet is cheaper, but also grossly ineffective. It will take a long time for the kid to learn what I did over the decades I spent doing it. Then it will be their code and a manifestation of who they are, so the problem persists.
Thursday, December 11, 2025
The Value of Data
According to Commodore Grace Hopper, back in 1985, the flow is: data -> information -> knowledge.
I really like this perspective.
Working through that, data is the raw bits and bytes that we are collecting, in various different ‘data types’ (formats, encodings, representations). Data also has a structure, which is very important.
Information is really what we are presenting to people. Mostly these days via GUIs, but there are other, older mediums, like print. The data might be an encoded Julian date, and the information is a readable printed string in one of the nicer date formats.
Knowledge, then, is when someone absorbs this information, and it leads them to a specific understanding. They use this knowledge to make decisions. The decisions are the result of the collection of data as it relates to the physical world.
A part of what she is saying is that collecting data that is wrong or useless has no value. It is a waste of resources. But we did not know back then how to value data, and 40 years later, we still do not know how to do this.
I think the central problem with this is ambiguity. If we collect data on something, and some or part of it is missing, it is ambiguous as to what happened. We just don’t know.
We could, for instance, get a list of all of the employees for a company, but without some type of higher structure, like a tree or a dag, we do not know who reported to whom. We can flatten that structure and embed it directly into the list, as say a column called ‘boss’, which would allow us to reconstruct the hierarchy later.
So, this falls into the difference between data and derived data. The column boss is a relative reference to the structural reporting organization. If we use it to rebuild the whole structure, then we could see all of the employees below a given person. The information may then allow someone to be able to see the current corporate hierarchy, and the knowledge might be that it is inconsistent and needs to be reorganized somehow. So, the decision is to move around different employees to fix the internal inconsistencies and hopefully strengthen the organization.
In that sense, this does set the value somewhat. You can make the correct decision if you have all of the employees, none are missing, none of them are incorrect in an overall harmful way, and you have a reference to their boss. The list is full, complete, and up-to-date, and the structural references are correct.
So, what you need to collect is not only the current list of employees and who they report to, but also any sort of changes that happen later when people are hired, or they leave, or change bosses. A snapshot and a stream of deltas that is kept up-to-date. That is all you need to persist in order to make decisions based on the organization of the employees.
Pulling back a bit, if we work backwards, we can see that there are possibly millions of little decisions that need to be made, and we need to collect and persist all of the relevant individual pieces of data, and any related structural relationships as well.
We have done this correctly if and only if we can present the information necessary without any sort of ambiguity. That is, if we don't have a needed date and time for an event, we at least have other time markers such that we can correctly calculate the needed data and time.
But that is a common, often subtle bug in a lot of modern systems. They might know when something starts, for instance, and then keep track of the number of days since the start when another event occurred. That’s correct for the date, but any sort of calculated time is nonsense. If you did that, the information you present would be the data only, but if you look at a lot of systems out there, you see bad data, like fake times on the screens. Incorrect derived information caused by an ambiguity caused by not collecting a required piece of data, or at very least, not presenting the actual collected and derived data on the screen correctly. It’s an overly simple example, but way too common for interfaces to lie about some of the information that they show people.
The corollary to all of this is that it seems unwise to blindly collect as much data as possible and just throw it into a data swamp, so that you can sort it out later. That never made any real sense to me.
The costs of modelling it correctly so it can be used to present information are far cheaper if you do it closer to when you collect the data. But people don’t want to put in the effort to figure out how to model the data, and they are also worried about missing data that they think they should have collected, so they collect it all and insist that they’ll sort it out later. Maybe later comes, sometimes, but rarely, so it doesn’t seem like a good use of resources. The data in the swamp has almost no real value, and is far more likely to never have any real value.
But all of that tells us that we need to think in terms of: decision -> knowledge -> information -> data.
Tell me what decisions you need to make, and I can tell you what data we have to collect.
If you don’t know, you can at least express it in general terms.
The business may need to react in terms of changes to the customer spending, for example. So, we need a system that shows at a high level and all of the way down, how the customers are spending on the products and services. And we need it to be historic, so that we can look at changes over time, say last year or five years ago. It can be more specific if the line of business is mature and you have someone whose expertise in that line is incredibly deep, but otherwise, it is general.
It works outwardly as well. You decide to put up a commercial product to help users with a very specific problem. You figure out what decisions they need to make while navigating through that problem, then you know what data you need to collect, and what structure you need to understand.
They are shopping for the best deals. You’d want to collect all of the things they have seen so far and rank them somehow. The overall list of all deals possible might get them going, but the actual problem is enabling them to make a decision based on what they’ve seen, not to overwhelm them with too much information.
The corollary to this is what effectively bugs me about a lot of the lesser web apps out there. They claim to solve a problem for the users, but then they just go and push back great swaths of the problem to the users instead. They’re too busy throwing up widgets onto the screen to care about whether the information in the widgets is useful or not, and they’ve organized the web app based on their own convenience, not the users' need to make a decision. Forcing the users to end up bouncing all over the place and copying and pasting the information elsewhere to refine the knowledge. It’s not solving the problem, but just getting in the way. A bad gateway to slow down access to the necessary information.
I’ve blogged about data modelling a lot, but Grace Hopper’s take on this helps me refine the first part. I’ve always known that you have to carefully and correctly model the data before you waste a lot of time building code on top.
I’ve often said that if you have made mistakes in the modelling, you go down as low as you can to fix them as early as you can. Waiting just compounds the mistake.
I’ve intuitively known when building stuff to figure out the major entities first, then fill in the secondary ones as the system grows. But the notion that you can figure out all of the data for your solution by examining the decisions that get made as people work through their problems really helps in scoping the work.
Take any sort of system, write out all of the decisions you expect people to make as a result of using it, and then you have your schema for the database. You can prioritize the decisions based on how you are justifying, funding, or growing the system.
Following that, first you decide on the problem you want to solve. You figure out which major decisions the users would need to make using your solution, then you craft a schema. From there, you can start adding features, implementing the functionality they need to make it happen. You still have some sense of which decisions you can’t deal with right away, so you get a roadmap as well.
Software essentially grows from a starting point in a problem space; if we envision that as being fields of related decisions, then it helps shape how the whole thing will evolve.
For example, if you want to help the users decide what’s for dinner tonight, you need data about what’s in the fridge, which recipe books they have, what kitchen equipment, and what stores are accessible to them. You let them add to that context, then you can provide an ordered list of the best options, shopping lists, and recipes. If you do that, you have solved their ‘dinner problem’; if you only do a little bit of that, the app is useless. Starting with the decision that they need help making clarifies the rest of it.
As I have often said, software is all about data; code is just the way you move it around. If you want to build sophisticated systems, you need to collect the right data and present it in the right way. Garbage data interferes with that. If you minimize the other resource usages like CPU, that is a plus, but it is secondary.
https://www.youtube.com/watch?v=ZR0ujwlvbkQ
I really like this perspective.
Working through that, data is the raw bits and bytes that we are collecting, in various different ‘data types’ (formats, encodings, representations). Data also has a structure, which is very important.
Information is really what we are presenting to people. Mostly these days via GUIs, but there are other, older mediums, like print. The data might be an encoded Julian date, and the information is a readable printed string in one of the nicer date formats.
Knowledge, then, is when someone absorbs this information, and it leads them to a specific understanding. They use this knowledge to make decisions. The decisions are the result of the collection of data as it relates to the physical world.
A part of what she is saying is that collecting data that is wrong or useless has no value. It is a waste of resources. But we did not know back then how to value data, and 40 years later, we still do not know how to do this.
I think the central problem with this is ambiguity. If we collect data on something, and some or part of it is missing, it is ambiguous as to what happened. We just don’t know.
We could, for instance, get a list of all of the employees for a company, but without some type of higher structure, like a tree or a dag, we do not know who reported to whom. We can flatten that structure and embed it directly into the list, as say a column called ‘boss’, which would allow us to reconstruct the hierarchy later.
So, this falls into the difference between data and derived data. The column boss is a relative reference to the structural reporting organization. If we use it to rebuild the whole structure, then we could see all of the employees below a given person. The information may then allow someone to be able to see the current corporate hierarchy, and the knowledge might be that it is inconsistent and needs to be reorganized somehow. So, the decision is to move around different employees to fix the internal inconsistencies and hopefully strengthen the organization.
In that sense, this does set the value somewhat. You can make the correct decision if you have all of the employees, none are missing, none of them are incorrect in an overall harmful way, and you have a reference to their boss. The list is full, complete, and up-to-date, and the structural references are correct.
So, what you need to collect is not only the current list of employees and who they report to, but also any sort of changes that happen later when people are hired, or they leave, or change bosses. A snapshot and a stream of deltas that is kept up-to-date. That is all you need to persist in order to make decisions based on the organization of the employees.
Pulling back a bit, if we work backwards, we can see that there are possibly millions of little decisions that need to be made, and we need to collect and persist all of the relevant individual pieces of data, and any related structural relationships as well.
We have done this correctly if and only if we can present the information necessary without any sort of ambiguity. That is, if we don't have a needed date and time for an event, we at least have other time markers such that we can correctly calculate the needed data and time.
But that is a common, often subtle bug in a lot of modern systems. They might know when something starts, for instance, and then keep track of the number of days since the start when another event occurred. That’s correct for the date, but any sort of calculated time is nonsense. If you did that, the information you present would be the data only, but if you look at a lot of systems out there, you see bad data, like fake times on the screens. Incorrect derived information caused by an ambiguity caused by not collecting a required piece of data, or at very least, not presenting the actual collected and derived data on the screen correctly. It’s an overly simple example, but way too common for interfaces to lie about some of the information that they show people.
The corollary to all of this is that it seems unwise to blindly collect as much data as possible and just throw it into a data swamp, so that you can sort it out later. That never made any real sense to me.
The costs of modelling it correctly so it can be used to present information are far cheaper if you do it closer to when you collect the data. But people don’t want to put in the effort to figure out how to model the data, and they are also worried about missing data that they think they should have collected, so they collect it all and insist that they’ll sort it out later. Maybe later comes, sometimes, but rarely, so it doesn’t seem like a good use of resources. The data in the swamp has almost no real value, and is far more likely to never have any real value.
But all of that tells us that we need to think in terms of: decision -> knowledge -> information -> data.
Tell me what decisions you need to make, and I can tell you what data we have to collect.
If you don’t know, you can at least express it in general terms.
The business may need to react in terms of changes to the customer spending, for example. So, we need a system that shows at a high level and all of the way down, how the customers are spending on the products and services. And we need it to be historic, so that we can look at changes over time, say last year or five years ago. It can be more specific if the line of business is mature and you have someone whose expertise in that line is incredibly deep, but otherwise, it is general.
It works outwardly as well. You decide to put up a commercial product to help users with a very specific problem. You figure out what decisions they need to make while navigating through that problem, then you know what data you need to collect, and what structure you need to understand.
They are shopping for the best deals. You’d want to collect all of the things they have seen so far and rank them somehow. The overall list of all deals possible might get them going, but the actual problem is enabling them to make a decision based on what they’ve seen, not to overwhelm them with too much information.
The corollary to this is what effectively bugs me about a lot of the lesser web apps out there. They claim to solve a problem for the users, but then they just go and push back great swaths of the problem to the users instead. They’re too busy throwing up widgets onto the screen to care about whether the information in the widgets is useful or not, and they’ve organized the web app based on their own convenience, not the users' need to make a decision. Forcing the users to end up bouncing all over the place and copying and pasting the information elsewhere to refine the knowledge. It’s not solving the problem, but just getting in the way. A bad gateway to slow down access to the necessary information.
I’ve blogged about data modelling a lot, but Grace Hopper’s take on this helps me refine the first part. I’ve always known that you have to carefully and correctly model the data before you waste a lot of time building code on top.
I’ve often said that if you have made mistakes in the modelling, you go down as low as you can to fix them as early as you can. Waiting just compounds the mistake.
I’ve intuitively known when building stuff to figure out the major entities first, then fill in the secondary ones as the system grows. But the notion that you can figure out all of the data for your solution by examining the decisions that get made as people work through their problems really helps in scoping the work.
Take any sort of system, write out all of the decisions you expect people to make as a result of using it, and then you have your schema for the database. You can prioritize the decisions based on how you are justifying, funding, or growing the system.
Following that, first you decide on the problem you want to solve. You figure out which major decisions the users would need to make using your solution, then you craft a schema. From there, you can start adding features, implementing the functionality they need to make it happen. You still have some sense of which decisions you can’t deal with right away, so you get a roadmap as well.
Software essentially grows from a starting point in a problem space; if we envision that as being fields of related decisions, then it helps shape how the whole thing will evolve.
For example, if you want to help the users decide what’s for dinner tonight, you need data about what’s in the fridge, which recipe books they have, what kitchen equipment, and what stores are accessible to them. You let them add to that context, then you can provide an ordered list of the best options, shopping lists, and recipes. If you do that, you have solved their ‘dinner problem’; if you only do a little bit of that, the app is useless. Starting with the decision that they need help making clarifies the rest of it.
As I have often said, software is all about data; code is just the way you move it around. If you want to build sophisticated systems, you need to collect the right data and present it in the right way. Garbage data interferes with that. If you minimize the other resource usages like CPU, that is a plus, but it is secondary.
Thursday, December 4, 2025
Expressive Power
You can think about code as just being a means to take different inputs and then deliver a range of related outputs.
In a relative sense, we can look at the size of that code (as the number of lines) and the range of its outputs. We can do this from a higher system perspective.
So, say we have a basic inventory system. It collects data about some physical stuff, lets people explore it a bit, then exports the data downstream to other systems. Without worrying about the specific features or functionality, let's say we were able to get this built with 100k lines of code.
If someone could come along and write the exact same system with 50K lines of the same type of code, it is clear that their code has more ‘expressive power’ than our codebase. Both are doing the same thing, take the same inputs, generate the same range of outputs, use the same technologies, but one is half the amount of code.
We want to amplify expressive power because, ultimately, it is less work to initially build it, usually a lot less work to test it, and it is far easier to extend it over its lifetime.
The code is half the size, so half of the typing work. Bugs loosely correlate to code size, so there are relatively half the number of bugs. If the code reductions were not just cute tricks and syntactic sugar, it would require a bit more cognitive effort to code, and bug fixing would be a little harder, but not twice, so there is still some significant savings. It’s just less brute force code.
Usually, the strongest way to kick up expressive power is code reuse with a touch of generalization.
Most systems have reams of redundant code; it’s all pretty much the same type of similar work. Get data from the database, put it on a screen, and put it back into the database again. With a few pipes in and a couple out, that is the bulk of the underlying mechanics.
If you can shrink the database interaction code and screen widget layout code, you can often get orders of magnitude code reductions.
But the other way to kick up expressive power is to produce a much larger range of outputs from the inputs. That tends to come from adding lots of different entities into the application model, some abstraction, and leveraging polymorphism everywhere. More stuff handled more generally.
For instance, instead of hard-coding a few different special sets of users, you put in the ability to group any of them for any reason. One generic group mechanism lets you track as many sets as you need, so it’s less screens, less specific entities, but a wider range of capabilities. A bump up in expressive power.
The biggest point about understanding and paying attention to expressive power comes from the amount of time it saves. We’re often asked to grind out medium-sized systems super quickly, but a side effect of that is that the specifications are highly reactive, so they change all of the time. If you build in strong expressive power early, then any of those arbitrary changes later become way less work, sometimes trivial.
If, from the above example, you had hardcoded sets, adding a new one is a major pain. If you had arbitrary groups, it would be trivial.
Brute force code is too rigid and fragile, so over time, it counts as dead weight. It keeps you from getting ahead of the game, which keeps you from having enough time to do a good job. You’re scrambling too hard to catch up.
We see that more dramatically if we write 1M lines of code, when we just needed 50K. 1M lines of code is a beast, so any sort of change or extension to it goes at a snail's pace. And adding new subsystems into something that brute-forced is the same work as doing it from scratch, so there is no real ability to leverage any of the earlier efforts. The code becomes a trap that kills almost all momentum. Development grinds to a halt.
But if you have some solid code with strong expressive power, you can use it over and over again. Sometimes you’ll have to ratchet it up to a new level of expressiveness, but it is a fraction of the work of coding it from scratch. Redeploying your own battle-hardened code a whole bunch of times is far superior to writing it from scratch. Less work, less learning, and way less bugs.
Since time is often the biggest development problem and the source of most problems, anything to save lots of time will always make projects go a whole lot smoother. To keep from getting swamped, we always need to get way more out of any work. That is the only way to keep it sane.
In a relative sense, we can look at the size of that code (as the number of lines) and the range of its outputs. We can do this from a higher system perspective.
So, say we have a basic inventory system. It collects data about some physical stuff, lets people explore it a bit, then exports the data downstream to other systems. Without worrying about the specific features or functionality, let's say we were able to get this built with 100k lines of code.
If someone could come along and write the exact same system with 50K lines of the same type of code, it is clear that their code has more ‘expressive power’ than our codebase. Both are doing the same thing, take the same inputs, generate the same range of outputs, use the same technologies, but one is half the amount of code.
We want to amplify expressive power because, ultimately, it is less work to initially build it, usually a lot less work to test it, and it is far easier to extend it over its lifetime.
The code is half the size, so half of the typing work. Bugs loosely correlate to code size, so there are relatively half the number of bugs. If the code reductions were not just cute tricks and syntactic sugar, it would require a bit more cognitive effort to code, and bug fixing would be a little harder, but not twice, so there is still some significant savings. It’s just less brute force code.
Usually, the strongest way to kick up expressive power is code reuse with a touch of generalization.
Most systems have reams of redundant code; it’s all pretty much the same type of similar work. Get data from the database, put it on a screen, and put it back into the database again. With a few pipes in and a couple out, that is the bulk of the underlying mechanics.
If you can shrink the database interaction code and screen widget layout code, you can often get orders of magnitude code reductions.
But the other way to kick up expressive power is to produce a much larger range of outputs from the inputs. That tends to come from adding lots of different entities into the application model, some abstraction, and leveraging polymorphism everywhere. More stuff handled more generally.
For instance, instead of hard-coding a few different special sets of users, you put in the ability to group any of them for any reason. One generic group mechanism lets you track as many sets as you need, so it’s less screens, less specific entities, but a wider range of capabilities. A bump up in expressive power.
The biggest point about understanding and paying attention to expressive power comes from the amount of time it saves. We’re often asked to grind out medium-sized systems super quickly, but a side effect of that is that the specifications are highly reactive, so they change all of the time. If you build in strong expressive power early, then any of those arbitrary changes later become way less work, sometimes trivial.
If, from the above example, you had hardcoded sets, adding a new one is a major pain. If you had arbitrary groups, it would be trivial.
Brute force code is too rigid and fragile, so over time, it counts as dead weight. It keeps you from getting ahead of the game, which keeps you from having enough time to do a good job. You’re scrambling too hard to catch up.
We see that more dramatically if we write 1M lines of code, when we just needed 50K. 1M lines of code is a beast, so any sort of change or extension to it goes at a snail's pace. And adding new subsystems into something that brute-forced is the same work as doing it from scratch, so there is no real ability to leverage any of the earlier efforts. The code becomes a trap that kills almost all momentum. Development grinds to a halt.
But if you have some solid code with strong expressive power, you can use it over and over again. Sometimes you’ll have to ratchet it up to a new level of expressiveness, but it is a fraction of the work of coding it from scratch. Redeploying your own battle-hardened code a whole bunch of times is far superior to writing it from scratch. Less work, less learning, and way less bugs.
Since time is often the biggest development problem and the source of most problems, anything to save lots of time will always make projects go a whole lot smoother. To keep from getting swamped, we always need to get way more out of any work. That is the only way to keep it sane.
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