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Even when viewing the subject in the most objective way possible, it is clear that software, as a product, generally suffers from low quality.

Take for example a house built from scratch. Usually, the house will function as it is supposed to. It will stand for many years to come, the roof will support heavy weather conditions, the doors and the windows will do their job, the foundations will not collapse even when the house is fully populated. Sure, minor problems do occur, like a leaking faucet or a bad paint job, but these are not critical.

Software, on the other hand is much more susceptible to suffer from bad quality: unexpected crashes, erroneous behavior, miscellaneous bugs, etc. Sure, there are many software projects and products which show high quality and are very reliable. But lots of software products do not fall in this category. Take into consideration paradigms like TDD which its popularity is on the rise in the past few years.

Why is this? Why do people have to fear that their software will not work or crash? (Do you walk into a house fearing its foundations will collapse?) Why is software - subjectively - so full of bugs?

Possible reasons:

  • Modern software engineering has existed for only a few decades, a small time period compared to other forms of engineering/production.
  • Software is very complicated with layers upon layers of complexity, integrating them all is not trivial.
  • Software development is relatively easy to start with, anyone can write a simple program on his PC, which leads to amateur software leaking into the market.
  • Tight budgets and timeframes do not allow complete and high quality development and extensive testing.

How do you explain this issue, and do you see software quality advancing in the near future?

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closed as primarily opinion-based by Juhana, Jeroen, David Souther, greg-449, Ganesh Sittampalam Dec 22 '13 at 15:59

Many good questions generate some degree of opinion based on expert experience, but answers to this question will tend to be almost entirely based on opinions, rather than facts, references, or specific expertise.If this question can be reworded to fit the rules in the help center, please edit the question.

53 Answers 53

The problem with the Software Quality 'movement' is that it used manufacturing as its basis. The issue with verifying (inspecting) the quality of software during production is that (compared to its physical manufactured counter part) it is invisible. Over the years schemes of Software Quality Characteristics (such as the FURPS model) have been devised to identify and measure desired characteristics during and just after software production. The search for an elusive set of measurable quality characteristics continues today (with ISO 9126 being recently released), in an attempt to quantify a medium that is non-physical, in order to control and measure its overall quality (or fitness for purpose).

If we look to Agile processes, that is short 10 day sprints, we are moving away from the manufacturing analogies and taking advantage of the ability to change software quickly (as opposed to fixing a physical part). I believe this direction, rather than trying to retrofit the manufacturing QA\QC model, will yield more 'quality' in software although ultimately the essential difficulties of the software medium (invisible) will remain and we will continue to look for more useful characterization schemes and delivery models to produce a better result.

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I think the poster's answers pretty much cover it.

Two things I'd add:

  1. Software moves and changes so rapidly, it's hard for developers to stay focused on quality.

  2. The legal system hasn't caught up to the software industry yet - when you'll be able to recover damages for crappy software like you can for a crappy car or house, and when software makers are forced to WARRANTY their products instead of filling their EULA with every sort of disclaimer imaginable, quality will undoubtedly improve...

Do I see things improving? They've already improved a great deal, and will continue to improve as users grow more sophisticated and the legal system catches up, forcing QC to become more important than feature bloat.

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Software is a custom designed product, not a manufactured product. Sure, every copy of a software is manufactured, but the actual software is pretty much custom written for each application. So, the issue of quality is much more difficult than say for cars where the same model is created millions of times, during which period the bugs are worked out.

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I think it has a lot to do with the malleable nature of software.

Because software is heavily modified over time, it's important for it to be designed such that changes in one part of the software don't affect other parts of the software. Even though principles for addressing this are widely understood in our field, there are a couple of problems. The first is that there are plenty of individual practicioners who don't understand or care about those principles. The other is that there can be competing forces that cause us to violate those principles (budget, schedule, or even engineering concerns such as performance engineering). So over time software becomes complex and brittle unless you apply constant discipline to prevent that outcome.

Another piece is that because everybody (developers, managers, even customers) understands software is malleable, people have at least some level of comfort with the idea that if there's a bug, we'll fix it with the next release or patch. I've often heard it said that it's more expensive to fix prod bugs than QA bugs, and more expensive to fix QA bugs than dev bugs, etc., and given the economics we should do things like QA and unit testing. And ultimately I agree, but the idea can be carried too far. If you're able to find the bug via unit testing or QA, yeah, you're better off, but there's a cost associated with finding the bug in the first place, and diminishing returns kicks in pretty quickly due to the underlying complexity of the system (e.g. combinatorial explosions in the number of possible configurations). So the economics mandate catching most problems in dev/QA by investing in training, code reviews, testing disciple, etc., but not trying to be exhaustive, because in most cases the costs of fixing user-discovered bugs is reasonable. This is very different than most consumer products, where the cost associated with fixing bugs is great. The ROI for catching problems early is much greater if a late discovery is going to mean a recall or pulling something off the shelves.

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To go with the building example: It's like you build a small hut, and after being half done building it the owner comes along and says: "Look, I thought about it and I'd rather have a villa." - So you change the building, but the fundament has already been laid, so you have to modify what's already there. The owner comes back after two months and says "Guys, one bathroom is not enough. I'd rather have three. It's done tomorrow, right?" And so on and so on. Good software engineering relies on permanent iterative re-architecturing over time. – Thorsten79 Aug 13 '10 at 8:06

Look at the expectations for software. All the if's and buts. Here would be the demands on the home:

  • I want the bedroom to be 20' X 20' unless I was asleep and need to go to the bathroom, then I want the bedroom to shrink so the bathroom is closer and all the furniture doesn't get crusehd.
  • During a tornado, get rid of all the windows.
  • The garage should have a turntable big enough to rotate a Hummer in .2 seconds.
  • the walls should be able to change colors based on the 'skin' I choose
  • make it scalable, I may want to invite all my facebook friends
  • adjust shower temp when toilet is flushed
  • the plumbing should never break since 'nothing has changed'
  • TVs, newspapers and magazines shouldn't show advertising if I pay my mortgage

Oh, and try to do as much of this as you can with open source building materials.

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"Take for example a house built from scratch. Usually, the house will function as it is supposed to. It will stand for many years to come, the roof will support heavy weather conditions, the doors and the windows will do their job, the foundations will not collapse even when the house is fully populated. Sure, minor problems do occur, like a leaking faucet or a bad paint job, but these are not critical."

This is clearly not true -- it's a really bad example. I've seen a large number of houses that are just shacks. Houses that can, and often do, simply collapse in heavy weather. They don't use windows and the door is a sheet of plywood.

To get away with building a shack instead of a house, you have to build your shack where there are no housing codes or standards. Or, you have to evade inspection by claiming you don't "live" there. Or you have to be heavily armed so that the inspectors don't bother you.

[bignose] Indeed. Also relevant is that many of us (including, I suspect, the person who wrote the original question) live in countries where housing is strictly regulated, and poor quality is considered unacceptable even if both builder and purchaser want to cut corners. In the absence of that enforced regulation, housing runs the whole range including ghastly deathtraps; that is what we see in the field of software.

Software quality is like all other forms of quality. The issue is this.

Most consumer products have warranties (expressed or implied). Some even have applicable standards for safety.

Consumer shrink-wrapped software specifically avoids offering a warranty of any kind. It's a sad, shabby business. To avoid warranty claims, they don't let you purchase software; you merely license it, or purchase a right to use. Read your EULA's. There's no warranty. Quality doesn't matter.

In-house software, developed by large IT organizations, has no warranty of any kind either. It's entirely based on corporate politics, internal reputation and influence.

Most of the time, most in-house software developers actually have good reputations and have earned those good reputations by providing outstanding levels of service.

But some software developers are slapping shacks together with cast-off plywood, pallets, blue poly tarps, and the remains of an old travel trailer that they found.

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interesting insight. – Chris Dec 8 '08 at 8:37
Also relevant is that many of us live in countries where housing is strictly regulated, and poor quality is considered unacceptable even if both builder and purchaser want to cut corners. In the absence of that enforced regulation, housing runs the whole range including ghastly deathtraps; that is what we see in the field of software. – bignose Mar 23 '10 at 6:08

I have to disagree with your rant. Considering the dynamic nature of software, I think it is quite amazing that stuff works as good as it does. Just look at the thousands of different hardware windows has to support.

That would be like building the same house design in a thousand different types of soil, elevations, mountains, water, and it has to keep from collapsing.

And to use another analogy, in a computer system, unlike in the real world, the "laws of physics" change based on the operating system you are building in. Further, sometimes these "laws of physics" can also be buggy / inconsistent, causing your software to behave in an unexpected way.

In the real world you would never find that north and south pole suddenly flips whenever the wind happens to blow a certain way in combination with the sun being in a certain level in the sky.

Things like this happen all the time in software, because of the extreme dynamic nature and complexity, when large systems interact with each other it is nearly impossible to predict all of the potential points of failure.

Because each system may have "physics" which behave very differently. In the real world there is only one law of physics and it behaves consistently, it can be accurately measured, and allows us to use mathematics to predict future behavior in various scenarios.

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Well, my belief is that it's a matter of changing from Monolithic Apps to Modular Apps by using something similar to the Lego Process which can be checked out here

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Fred Brooks, of mythical man month fame, had an interesting article a few years ago titled No Silver Bullet. This was just about the time that OO software and design was being talked about as the next silver bullet to all of our software design problems.

The basic idea was that software can be broken into two types of complexity, accidental and inherent.

Accidental complexity is using x86 assembly language rather than python to write a processing script.

You can do it with x86 assembly language, but, you'll spend a lot more time.

Accidental complexity can be solved with different languages, especially if you can get a language which maps well to your problem. The large number of languages show that we work hard to solve this problem.

The other sort of complexity, inherent complexity, is what is hard. This is not solved by languages etc and is what causes us the biggest headaches. This is where the leaky abstractions bite us, and where the library calls work in the order A, B, C, D, but, in spite of the documentation which say that you can call A, B, D, C, it fails later when you call F.

Also, of course, some problems are just hard at a basic level (US Taxes, for example) and no language helps here.

I'm not sure, in the end, that there is a good solution.

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In my opinion the following are at least partially responsible:

  • Thorough and complete testing is tedious and time consuming
  • Sometimes its less expensive to ship buggy software than it is to fix it (or, more likely, its perceived to be less expensive)
  • Lack of understanding of the problem being solved. If you don't completely understand what you are solving, its going to be difficult to do so without introducing bugs.
  • Most programmers are pretty bad programmers (my opinion, of course, but in my own experience, I'd say only one in five programmers really know what they're doing)
  • If a problem is complex, its easy to get lost in one aspect and neglect another
  • Some programming languages are too verbose, making it difficult to keep the whole problem in mind at any one time, which allows bugs to creep in (for example, I tend to make more mistakes in Java than in Python, it may just be coincidence, of course, but I feel that Pythons higher level code helps me solve problems in fewer discrete chunks, leaving less room for bugs)
  • Dependencies. I believe that dependencies (I mean calculations and data which depend on one another) are a major cause of bugs - when they're not managed properly anyway (dependents not getting updated when they should etc)
  • A lot of programmers are lazy or distracted causing them to make mistakes. I know I'm guilty of this sometimes.
  • Most programmers aren't rigorous or methodological enough when approaching a problem. Instead of carefully planning out a solution and verifying that it is correct (formally or otherwise), they instead dive in and start coding. I know I sometimes do this even though I know I shouldn't..
  • The tight coupling of operations (instructions, statements, code blocks, functions etc) makes code less dynamic and fluid, which makes it difficult to update code, determine where code should be split up, what code can be reused, what should run concurrently and so on. This is, IMHO, another large source of error and one thats not easily solved with existing code.

And probably many more factors which I have forgotten about.

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It's hard. There are X number of ways to solving many issues. Programmers rely on a lot of third party libraries, which will abstract away from you what is really going on.

When doing web development you have many browsers and potential settings to worry about. Desktop development has different operating systems, and settings to worry about.

People get hired based off answering questions and not writing code. There was a member on my team on a very large, highly visible web application, and she had no idea how to write code. She lasted six months. She never would have made it past the interview if someone would have simply had her write a reverse string method on a white board.

Also, the ever evolving nature of technology, means theres always something new and amazing around the corner. I'm not expert, but I imagine there are only a few ways to build a skyscraper or a highway. There are tons of different ways to build a web application.

I'd also highly recommend reading Joel Spolsky's awesome article about Leaky Abstractions

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I disagree. The state of software development is exactly the way your house example is like. On first glance, everything in the house looks fine (maybe even work fine). Simple stuff works without a hitch. But when a really big winds come, some houses lose its roof. Better houses suffers minor damage but still live on. Like software does. On first glance, everything in the software looks fine (maybe even work fine). But when you pushed it to limit (For a web server, gives it a high load testing). Some softwares crash altogether. Better software do weird things but still works fine.

Some houses works fine during the first few years. However, as time goes by, things start to break. Like software does. Most software works fine during the first few years. However, as time goes by, new drivers gets installed, new OS patches got patched, new applications gets installed, some (bad) software simply stops working. Like for examaple some software designed for Windows XP simply wouldn't run in Windows 7.

To conclude, yes, there is no perfect software like there is perfect house. Most of the time, it depends on the amount of work that is being done to create the software/house. Lots of time and lots of money it's most certainly going to be good. Done hastily and cheaply it's most certainly going to be bad. Well, just like a house.

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Software has to be sold to managers and/or regular people. If you're regular person you can tell good house from bad one, or working TV from broken one. However, non-tech person can't distinguish between good software and bad software.

When the ones who pay for the product can't tell the difference, the result drifts to the bottom of the pool in terms of quality.

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I tried around 5 times to make that link a link. I give up. Anyway Gresham's Law extends to any situation where low quality is accepted in place of high quality.

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In software engineering it's possible to put the dunny on the ceiling.

GeneralFushException: Duck!
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Consider this:

  1. Software is very very difficult to inspect compared to a house or a car. Unlike the latter, you just can't glance over a piece of code and spot defects. You have to read and comprehend it.
  2. Software is usually many times more complex than other engineering artifacts, like cars. That's because it is infinitely more flexible. In physical objects, you hit a limit on complexity very early for reasons like manufacturablity, purchasing cost, shipping cost etc. In software, these constraints either don't apply, or do so mildly if at all.
  3. Software, once created, continues to change. Cars and houses once manufatured stay largely the same. But software artifacts can practically morph into something else in a few year's time. And every change has a potential to break existing funcationality, and mostly it does.

In other words, engineering software is much harder than engineering a car or a house.

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People often draw the parallels between software engineering, which they see as full of problems, and other forms of engineering, which they see as not so problematic.

Your parallel between housing development and software development is not so good for several reasons:

  • You maintain your house day in day, repair it, upgrade it and etc.
  • Your house was built in one spot and was designed for that spot.
  • Your house has much less complex functionality then the average product
  • House building has strict predetermined calculations/rules/regulations
  • House building has been around for thousands of years, so they have wrinkled out the bugs

But the biggest difference between software engineering and other types of engineering is that they have been basically using TTD while the software engineering has so far been heavily on the trail & error process.

I say they use TTD since they have plans, prototypes and tests for those prototypes before going in to massive production and with all of that they still tend to have problems here and there like the leaking faucet or and oil leak from your car caused by poor manufacturing.

My point being that other engineering disciplines also result in bugs and problems but the main difference is that they don't result in a big red X mark with an error description you can't understand.

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Bugs are a part of the uncertainty and incomplete requirements that tends to happen with IT projects. Software won't work because as someone sees the program running, then she or he will think of, "Well, it should also do this, that and this other thing here," which while it can be done isn't what was originally requested. To take the house example a bit further, software may be viewed as the paint on the walls and furniture in the house which can easily be changed or moved which can lead to some people not being happy with their home since it is missing something that they want.

I don't see software quality advancing due simply to how poorly thought out various IT projects tend to be set up. While in the house things like doorways and floors are nailed down pretty much, there aren't similar things with software as there are usually dozens of different hardware configurations that will work with the software, but what is optimal and how can this be determined based on how a given company will use the servers that perform a set of tasks related to a specific process like Resource Planning or Customer Service.

Software development methodologies like Agile and Scrum exist as a way to try to give someone something close to what they want and then allowing changes that improve the product done repeatedly. So, for example as a house is being built, someone wouldn't change where the staircases go or where the windows will be yet in software these kinds of changes are likely to be common where the UI, being as flexible as it is, has to get refined over many many tries and even then there is a question of what point do you call it "done"?

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A lot of people seem to be suggesting that software would be more reliable if it had fewer features. After all, most users only use a small subset of the features of many applications. The problem lies in the fact that different users use a different subset of features.

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For me its the developers, that are the source of low quality software.

Like the early ages of craftmanship, developing software is handmaking software. Most developers tend to pretend, to do everything by hand, build it on their own. But this costs time, and time is money and money makes the world go round.

Projects today have to be fast done and cheap - that bites with the developers view.

I think software developing needs to get to the next phase, the industrial revolution.

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Check out this related question.

A lot of responders here are blaming these defects on unskilled software developers.

I think the problem is far deeper and more interesting than that.

A great deal of software comes out of engineering institutions who hire solid people and put enormous energy into getting things right. There are QA departments, methodologies, policies like peer code review, etc.

And still a shocking percentage of projects have serious problems or fail utterly, never delivering anything of use.

How is that possible? We should have this down by now, right?

If you ask the people in charge, they might blame the budget. And of course that's often the final straw, the thing that ostensibly forces the doors to close or the project to ship too early.

But that is often an extremely superficial answer designed to protect careers. After all, there wouldn't be budget problems if the project was planned and executed properly.

But that's easier said than done.

I think devs, even brilliant devs who do this a lot, sometimes fail to fully respect how time consuming and expensive it is to develop complex systems. (Here's a great book that shows you how this happens, among other things).

And running software projects, especially large ones, requires a specialized skillset that goes way beyond MS Project and even formal methodologies like Agile.

Here's an example: you have to be able to explain to stakeholders (who maybe have no point of reference and think software is easy) that what they want is going to take way longer than they expect. And sell that, even if there is enormous pressure - and there will be.

You have to educate delicately (after all, these are smart exec-types who are very sure of themselves), maybe telling a story about the old Waterfall methodology and why software projects fail, and why a counter-intuitive approach like Agile might be necessary, and sorry, not only does that mean your budget is not going to work, it could mean no fixed costs at all.

That can be tough because there is competition out there who will tell them what they want to hear and move forward with a plan that will most likely lead to chaos and defeat. Because people don't understand this stuff.

And that's just one little piece.

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I like the house analogy tossed around. When you build a house, you have a lot of slack in many areas. Even someone who knows nothing about building houses can learn it pretty quickly because the processes and the materials are "simple" and well understood. A piece of rock is not going to suddenly jump up and talk to your face. If you put it somewhere and you give it some support, it's going to stay there - period. Burned ceramics aren't going to let water through. You just have to find some goo to plug the gaps until the guarantee time is over and you're good.

With software, you have much more delicate and hidden dependencies. Since people don't understand this, here is my analogy: Chess has some pretty simple rules (roughly 20). If you need, you can enumerate them on one standard sized piece of paper (A4 or letter or whatever). Despite that, you can't enumerate all possible states of the system nor can you, given most states, tell how the system got there.

The Asian game of Go has even more simple rules (roughly 10). Contrary to intuition, Go has even more complex states and so far, no computer in the world has ever come even close to challenging a decent human player without a handicap.

Lastly, we have Conway's Game of Life. Four rules. 4. Read it again: Four (4). Game of Life is so complex that it's Turing Complete: You can build a fully working computer with it and compute anything that a computer can compute, for example, you can teach it to play Chess. Or to simulate a computer playing Conway's Game of Life. If you can write a program that can write a program that can play Conway's Game of Life. I wonder if She took precautions against "infinite recursive creation loops". Anyway.

Conclusion: While software may look simple, it never is. Every problem has at least an infinite amount of possible correct solutions and an even greater amount of wrong ones. If math allowed it, we would have to multiply this with the possible amounts of misunderstandings between the customer and the developer (multiplied by the levels of indirection between them, i.e. managers, customer relationship people, project managers, your co-workers), add the usual sprinkle of bugs in the environment you have to use and then ...

We wonder how it is even possible that anyone ever wrote a piece of code with more than 10 lines of code that actually works.

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I think alot of you have missed a major point. Software is invisible, we can only see the results from a given set of inputs and the whole process happens with out us able to see what it is doing.

When building a house we can see, touch and feel the process and adjust when its wrong. In software we cant do this, We use some inputs, get some outputs and then check to see if it what we wanted. If not we go back change some code and try again thus leading to quality problems because we might have a fluke set of inputs that just happens to give the right output and we will move on and cant see the errors and bugs under the surface.

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  1. software development is difficult and time-consuming
  2. software developers are not interchangable cogs
  3. quality takes time
  4. you get what you pay for

Ignoring one or more of the points above leads to poor software quality, every time, guaranteed. Though this may not cover all incidents of poor software quality, but I suspect that it chracterizes the vast majority of them!

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The quality of a product depens greatly on your expectations of it. For instance, I believe there are no good javascript debuggers on the market. Non of them are capable of what I want them to do.

Other people will say the current debuggers are good, simply because they're not even considering the possibilty that something more might be needed.

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Houses have time-proven blueprints. There's thousands of houses each exactly the same as the last.

No two pieces of software are the same. The only reason people write software is to do something new or different.

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Your analogy perfectly explains why software quality is hard. Houses are physical objects whose materials obey the laws of physics. The materials, architecture, and engineering qualities of a house can be physically and numerically analyzed. How else can a civil engineer describe down to the number pounds of rebar how to build a bridge across a windy span able to withstand high speed truck traffic and the bridge does not collapse? Newtonian Physics has rules that never vary. You can numerically prove how strong the bridge will be.

On the other hand, computer programming has the halting problem. No amount of analysis can prove that a given program fulfills its defined purpose. So even if you could assemble some dream team of super-programmers to work on your project. The program they deliver cannot be certified to fulfill your (non-trivial) requirements 100%.

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Moore's Law causes some of the problems. Unlike Civil Engineering, everything changes quickly, so that expertise, standards, and reliable components are obsolete long before they have matured. Before we can work out how to properly solve the problem, it's gone. Topical example: many-cores.

Civil Engineering has also absorbed new technologies (e.g. pre-stressed concrete), but it's many times slower, and it doesn't require the reinvention of everything.

I also think the fact that software is so malleable that we can reinvent everything, is a contributing factor towards the pace of change. :-) It's more expensive to build a house, so people are more circumspect. However, as someone said, you're not allowed to build a cheap, DIY ramshackle shack (in developed countries).

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I see time and time again that the marketplace does not reward software quality. Apple is a good example; for many years they had a superior product, but people would not pay. (Not just the up-front costs of Apple but also the costs to change from whatever they were using that year.)

I still see many people making buying decisions on the idea that 'more is better'. Both Microsoft and the Free Software Foundation have conditioned people to two pernicious ideas: 1. The product with more features is always better. 2. It is OK for software to fail once in a while. Because the people making buying decisions do not understand that simpler is better, there are tremendous economic incentives to create software that is complex but appears to have nice features.

War story: in the early 1990s, a friend of mine tried to write his dissertation using Microsoft Word. Everything went fine until his manuscript got to around a hundred pages. At that point Word refused to let him change it any more. The eventual fix was for him to double the amount of memory on his PC. In the early 1990s this was an expensive fix.

After it was all over I asked why he had chosen Word. His response:

I liked the alleged features.

People buy software on perception, not on reality. It doesn't matter if the reality of the software is that it is hard to use or doesn't work; if it looks good, people will buy it.

Friends of mine who study economics tell me that this behavior is the sign of an immature market and that when computing matures and the demand for computing stabilizes, things will be different. I am not so sure---I look at the market for automobiles, which have 100+ years of engineering knowhow put in, and I see a much bigger market for cars that make people feel good than I do for cars that are boring but just work. I look forward to a day when buyers reject programs for having too many features and insist on buying simple, boring programs that just work.

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+1, plus more if I could. Quality software sucks because quality is expensive. Really expensive. And people don't want to pay for it. – Greg D May 27 '09 at 13:06
Cars are status symbols so I don't think that's a good comparison ... hopefully software isn't a status symbol--for anybody. – rpflo Oct 10 '09 at 5:01
If you think the only difference between a quality car and an expensive car is status, you must have only driven one type of car. – notJim Nov 26 '09 at 9:49
Isn't you whole point undermined by the fact that Apple have been rewarded in the marketplace when they started doing things right, just after Steve Jobs returned? Their stock price has gone up greater than 100x in the last 15 years. – Matthew Lock Mar 23 '10 at 6:13
I was surprised to see a mention of Free Software Foundation. What have they done to perpetuate that idea that "more is better" and "it's okay to produce crap"? – Tshepang Apr 28 '10 at 19:04

I agree to all of your points. Especially:

  • It took e.g. mechanical engineering centuries to get to the current state where they are able to have exact knowledge about how to dimensionize a part, they have standard parts, ...
    Unfortunately that what is called "Software Engineering" so far mostly failed to deliver methods and tools that fulfill the same purpose for our trade. We are still in the middle age where some knowledge is there and can be applied for special areas, but no consistent standard theory of the software development process (and Tools supporting it) seems to exist so far. The reasons for that are too complex to discuss them here, mainly because they see the process of software development too superficially.
  • Software has got a complexity and fragility not found in other areas. E. g. a car has got number of parts in the four-digit or lower five-digit area (although some of them quite complex), a piece of software can have millions of statements.
    And noone would accept a car that is falling apart while you drive just because e.g. the ash tray overflows, would you?

Additional points:

  • The tools used by most people are far from "state of the art". E.g. the most common errors in C/C++ like pointer errors and buffer overflows can hardly happen in Pascal-style languages like Ada that have been available for decades.
  • Mechanical parts usually have some tolerance to overload. E.g. in aerospace parts are overdimensionized by 50% or more so that an undetected damage to a part will usually not cause a serious failure until (hopefully!) discovered during the next routine maintainance interval. Similiar concepts exist in other areas of engineering. Doing this in software development is much additional work (you need a customer who wants this and is willing to pay for it) and still not 100% safe most of the time due to the huge number of possible errors.
  • The industry leaders tend to either not making use of the state of the art or taint it when trying to implement it. E.g. C# has got some very good basic concepts, but the C-style syntax is confusing, error-prone trash, Pascal syntax is much clearer, and the security concept was tainted by the possibility of using unsafe code. Libraries still usually have only a C interface as the smallest common denominator.
  • Many people in the business lack a knowledge about the necessarity of building appropriate abstractions.
    E.g. operation systems usually have only two layers of security, user and system. If a process (e.g. some evil script in a web browser that has corresponding securiety holes) can get user access rights, it can violate all data that the user has access to.
    And if a user process can get system rights, it can do with the machine whatever it wants.
    Different, fine-grained concepts exist, but are hardly used for several reasons, including lazyness of the programmer or backward compatibility, but also because these have been fittet to APIs afterwards and therefore have neither good granularity nor good performance, but also being proprietary and unportable.
    The same applies for development tools. Why can a broken statement in a C/C++ program break data or even the program at a totally different location, causing unpredictable results? Why don't we have "unbreakable" standard parts?
  • People go to the limits of existing basic technologies or beyond instead of creating better basic technologies first.
  • Users got used to seeing failures as "normal", even serious ones that noone would accept in e.g. a car.
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