> Why don't members of staff know "Julia / Moonscript / ..." and if they don't why can't they logically reason about what's going on in the language without having used it?
If the bug is a shallow/algorithmic bug, that's reasonable. Recently I was helping someone debug some javascript code. Eventually, we found the problem was that, in javascript, that [11] < [2]. I'm not particularly knowledgeable on javascript, so I didn't know it did < comparison of arrays by string comparison. That's the kind of thing that really needs.
> If the student understands how to use the abstraction then they have likely learned something far more valuable. If you're assigning labs that consist of basic idioms that can be whisked away by common library functions then you might consider changing your curriculum to focus more on solving problems rather then codifying solutions.
This I just have to disagree with. I think it's valuable for students to learn how to implement quick sort. It's useful to learn how to implement big-integer arithmetic. It's useful to learn how you can "fake" Java-style inheritance with structs and function pointers, so you really understand what's going on under the hood.
Of course long term, you wouldn't typically implement these things yourself, but understanding the fundamentals is important.
Also, if I set a practical which involves (for example) connecting to a HTTP server, intending them to do the raw connection themselves, and they use a 3 line python program, using the standard library, have they really learnt anything at all?
There certainly is a place for giving students more freedom, particularly in later years. It's clear the modern world is moving into "slap together 50 javascript/python packages with string" type programs (and that's because it's a great way to be productive quickly), which universities don't currently teach that well. But don't throw the baby out with the bathwater!
> This I just have to disagree with. I think it's valuable for students to learn how to implement quick sort.
I'd rather the students kow how to implement large software architectures, keep line counts down, abstract problems correctly, and learn how things are done in the real world.
> It's useful to learn how to implement big-integer arithmetic
Not in my opinion. Maybe, maybe, show them how emulating FP math works but writing big-integer arithmatic functions is pretty useless for most people and is far too strait forward to require them to develop their skills of development software architectures.
> It's useful to learn how you can "fake" Java-style inheritance with structs and function pointers
You can't force them to learn patterns, you can only give them work that is better suited to using the patterns provided. You can even hint to your students "Hey you can make a get_car and get_bike and make a Drivable struct that has a Drivable->stear() and stear can be a function pointer!" Forcing them to use a pattern isn't useful.
> so you really understand what's going on under the hood
Using function pointers isn't really correct for how Java stores class/object information. This is kind of only used in virtual functions IIRC. When I've decompiled static bytecode you see stuff like LString(some function).
> Also, if I set a practical which involves (for example) connecting to a HTTP server, intending them to do the raw connection themselves, and they use a 3 line python program, using the standard library, have they really learnt anything at all?
You're assigning the wrong problem. Don't say "Make and HTTP request" say "implement an HTTP header parser". The problem is now language and abstraction agnostic and involves a much more complex problem who's complexity lays in the realm of the software organization. The HTTP Parser code can be used to read and write requests and the next lab can be to use your new library in a larger project. I think that is far more useful.
> There certainly is a place for giving students more freedom, particularly in later years. It's clear the modern world is moving into "slap together 50 javascript/python packages with string" type programs (and that's because it's a great way to be productive quickly), which universities don't currently teach that well. But don't throw the baby out with the bathwater!
There is a measurable reason for this and it's not because of productivity. It's about maintainableilty, consistency, and bug erradication. I'd love for you to read this paper Do Code Clones Matter? [0] to see what they have found.
Making it so people know how to:
* List all the featurs that a library will need
* Take those features and write them in a clean API
* Do it in the most clean language-specific way (ex Pythonic code)
* Distribution methodologies
* Maintainablilty and support of these libraries
* Using these, and others, libraries in larger applications
* Documentation & Technical writing
I'd really love it if you could email me and follow up after you read that paper and tell me what you think. My school username is jk369 and my school's email server is @njit.edu. (I've split this up to avoid spam)
I will look at your paper, but I think it depends what your target is, for students.
Many of our students go on to do PhDs. For that an understanding of deep algorithmics is much more important than being able to use and distribute a library, or building larger applications. They need, in their field of student, to be able to reimplement and understand many important difficult algorithms, not (for example) put together some node.js libraries.
However, there is a place for that kind of degree. Someone once said to me something which stuck with me: "You wouldn't try to merge a maths, and accounting degree, just because they both contain numbers", yet that's still what we do in computer science.
I just want to make sure, and state for everyone, that I'm far too lazy to do work that good. That's done by people much further along in their development of their profecian then I. Not my work just something that I think is good.
> Many of our students go on to do PhDs. For that an understanding of deep algorithmics is much more important than being able to use and distribute a library, or building larger applications
It depends on what their PhD or major is. Many CS majors here go into math and physics and they would have done better to learn how to write pythonic (or matlabic?) code and learn how to correcly design APIs. For instance, tonight I'm going to be rewriting a library from Python 2 to Python 3 and I have no way to tell if there's been any regression because of a lack of testing frameworks, consistentcy in APIs and lack of modularity. I'd be basically impossible for me to mock even single parts of this.
> They need, in their field of student, to be able to reimplement and understand many important difficult algorithms, not (for example) put together some node.js libraries.
I don't think left-pad is a good charictarization of my position here. I think that the hardest part of large scale software development is the architecture portion and that's mainly because very few people ever actually start large complex projects on their own and no universities offer courses in such a field that practicies that.
> However, there is a place for that kind of degree. Someone once said to me something which stuck with me: "You wouldn't try to merge a maths, and accounting degree, just because they both contain numbers", yet that's still what we do in computer science.
The moment you, or one of your coworkers, creates a major like that (Software Engineering and Developemnt or something) I'll be transfering over from my Computer Science degree. It's useless for anything but the name and the prestige that gets my foot in the door for a lot of very fun and interesting opportunities. I've had to hobcobble together everything I've needed to learn from a software perspective on reverse engineering, bare-metal systems devlopment, assembly, networking, game development, operating system development, web development, and many abstractions/patterns that go along with all of those. It was very difficult and I'd rather have given 30k/year over 4 years to a school who could teach me the "real" way from "professionals" and end up with a piece of extremely expensive framed paper that says my name and "degree" on it.
I'd also like for a school to hold my hand while exploring different paradigms.
If the bug is a shallow/algorithmic bug, that's reasonable. Recently I was helping someone debug some javascript code. Eventually, we found the problem was that, in javascript, that [11] < [2]. I'm not particularly knowledgeable on javascript, so I didn't know it did < comparison of arrays by string comparison. That's the kind of thing that really needs.
> If the student understands how to use the abstraction then they have likely learned something far more valuable. If you're assigning labs that consist of basic idioms that can be whisked away by common library functions then you might consider changing your curriculum to focus more on solving problems rather then codifying solutions.
This I just have to disagree with. I think it's valuable for students to learn how to implement quick sort. It's useful to learn how to implement big-integer arithmetic. It's useful to learn how you can "fake" Java-style inheritance with structs and function pointers, so you really understand what's going on under the hood.
Of course long term, you wouldn't typically implement these things yourself, but understanding the fundamentals is important.
Also, if I set a practical which involves (for example) connecting to a HTTP server, intending them to do the raw connection themselves, and they use a 3 line python program, using the standard library, have they really learnt anything at all?
There certainly is a place for giving students more freedom, particularly in later years. It's clear the modern world is moving into "slap together 50 javascript/python packages with string" type programs (and that's because it's a great way to be productive quickly), which universities don't currently teach that well. But don't throw the baby out with the bathwater!