for some reason when i try to run this test the rollMany function is not defined
from Game import Game
import unittest
class BowlingTest(unittest.TestCase):
def setUp(self):
self.g = Game()
def rollMany(self,n,pins):
for i in range(n):
self.g.roll(pins)
def test_gutterGame(self):
rollMany(self,20,0)
self.assertEquals(0,self.g.score())
i also tried defining it inside of the setUp function in case the unittest only inits functions with test in its name, or whats in setUp
no luck, and i also even tried appending test_ in front of all occurrences of rollMany and got the same error
Annoying perhaps, but that's how self in Python works. So different from other OO languages? Perhaps the explicit self argument in the method signature seems like cruft, but self.method() to invoke method on self is how that would be done in Java and C++ as well.
@PaulMcG If I understood the reasoning correctly, the explicitness allows for something other than self to be passed? First thought is passing cls, but in theory you could pass another object entirely if you wanted to perform some trickery/magic?
Oooh I now have WSL2. Shiny. Of course now I can't remember what I wanted WSL1 to do that it didn't, and thus, the reason why I'm excited about having WSL2..
Well, it's certainly possible to reference the method as class.method(obj). For instance, you could take care of those pesky newlines when iterating over a file using with open('a.txt ' as f: for line in map(str.rstrip, f):
@toonarmycaptain It also vastly simplifies the implementation, since methods are just functions. The Python compiler has very little work to support classes – mainly name mangling and expanding argumentless super(). The largest bulk of functionality is provided by actual objects, such as type and function – one could in principle implement these in Python directly, and they would work.
Larry Wall has some very interesting notes and research into programming language linguistics. Very insightful, but kinda misses that PLs generally should not be prose but technical.
We have PERL used for some mission-critical middleware, designed for a factor 10 to 100 less of where we are today. It really is awful in production.
@CodyGray :) TIMTOWTDI makes Perl very flexible, but it also contributes to making Perl code harder to read. In contrast, Python's attitude of "There should be one — and preferably only one — obvious way to do it." makes Python code easier to read, once youre familiar with the language.
The "one obvious way to do it" approach means that you get recognizable idioms for many common programming tasks. So when you see code doing unusual stuff, it means that it's either doing something very special, or that the coder is doing something sub-optimal, or downright wrong.
Unfortunately, there are a few features in Python that break the "one obvious way to do it" principle, mostly for historical reasons. The main one being that we have several different ways to do string formatting.
Can someone have a look at this question? It's been voted as opinion based, but I don't see that as applicable ("needs details" I would understand). Haven't found a dupe and it's something that wasn't obvious to me, so might be worth salvaging.
@MisterMiyagi I voted to reopen. The people who voted to close it as opinion-based need to read & understand your answer. ;)
@CodyGray I learned C in 1980. I never got around to learning C++. I figured I'd wait for the language to stabilize, but then it kinda grew out of control. ;)
New features do get added, but backwards-compatibility is maintained, and you can write perfectly clear, understandable code without knowing all the new features. And you can start integrating them gradually, as you find a need for them. That's what I do. I don't claim to know everything that the language offers.
@CodyGray Thanks. I've pondered these dupes targets as well, but they don't really apply. import can be subtle. Talk about having one obvious way to do it... ^^
@CodyGray Sure, but it's very big. I've heard that it's difficult for someone to master all facets of C++. And I'm getting a bit too old to learn a new language. :)
@CodyGray I honestly doubt that anyone uses all of it. It took me years to find use-cases for some things (cough metaclass cough) even when explicitly searching for an excuse to use them.
@CodyGray Sure. You can be an expert Python coder without learning what features even exist in all of the standard Python libraries, what to speak of the numerous 3rd party libraries. However, the core language itself, minus the libraries, is fairly small. It does have a few obscure nooks & crannies, but they mostly concern fairly advanced stuff that you generally don't need in day-to-day coding.
I suppose it's a bit like in C, where stdio.h & stdlib.h aren't strictly part of the core language, but you generally need to know them to write useful C code. (Ok, you might not even have stdio in an embedded environment).
Indeed, I have worked in such an embedded environment. Although, really, it's more common to lack stdlib's memory allocation functions than stdio's output functions. Most embedded systems have some kind of console for debugging.
@CodyGray It's a bit of a grey area with Python. The language itself does not include many features associated with it. Writing code without the implicit builtins library is outright impossible, and some specific tasks just aren't practical without library support.
I used the old "chevron" file arg to print, too. Mostly for stderr. When I first started with Python, having a print statement instead of a function seemed regressive, like going back to Basic. I even wrapped it a function for a while, but I decided that was just being silly (& inefficient).
@CodyGray The print statement vs function stuff is pretty trivial, and can generally be fixed by the 2to3 conversion program. The biggest backwards compatibility issue is the difference between Python 2 & Python 3 handling of strings and bytes. The Python 2 way had... problems.
@CodyGray I can live without long-term backwards compatibility surprisingly well. Most of the things I have to fix at my dayjob are outdated crap that people never bothered to get up to date. Forcing people to maintain code has some appeal.
And of course there's a ton of Py 2 code out there in the wild that doesn't handle Unicode properly, it just appears to if it only ever encounters Latin1 encoded stuff. But throw an emoji at it and it will do Bad Things.
@AndrasDeak That's it, basically. The performance of that one Python script taking 10 seconds to deploy some 10k to 100k C++ data crunchers for days is completely irrelevant.
@CodyGray :) In Python 3, it's pretty straightforward: you encode Unicode strings to bytes, and decode bytes to Unicode strings. In Python 2, coders tend to try random combinations of encoding & decoding until they stumble on something that appears to work. Unless they know what they're doing. ;)
In Python 3, strings are immutable sequences of Unicode characters, and we're isolated from the underlying representation. We have an immutable bytes type & a mutable bytearray type for sequences of actual raw bytes.
Hi @abarnert! It's great to see that you're active on SO again. FWIW, one of my favourite lines on SO comes from one of your answers: "It doesn't make sense for a = 2 to turn the number 1 into the number 2 (that would give any Python programmer way too much power to change the fundamental workings of the universe); what it does instead is just make a forget the 1 object and point at the 2 object instead".
Well, admittedly, it does impact performance. OTOH, it does mean that Python's OOP is very pure. We don't have primitives & objects, we only have objects.
But as mentioned earlier, performance isn't really an issue. Eg, a program that needs to do a lot of number crunching uses Numpy to do the heavy lifting, and the Numpy stuff runs at compiled speed.
So, perhaps a ridiculous question, but one that I cannot answer. Why is there not a Python compiler that can take Python code and compile it into machine code? It could be as simple as a front-end for Clang or GCC, which would then leverage the toolchain's existing backends that generate machine code. All you'd need to do was turn Python into an intermediate code.
That would give you the best of both worlds. You have a nice, modern language, and one that can be interpreted (e.g., for super simple debugging and investigation), but when you're finished, you can compile it into something efficient.
In Python, we don't optimize for running speed, we optimize for development speed. I.e., good Python code is code that's fast for humans to write and to read.
I am a huge fan of compilers for two reasons: (1) generation of more efficient code, and (2) compile-time correctness checking (i.e., static checks for types, behavior, etc.).
Classes in Python are maleable. You can add and remove methods, fields and attributes at any time. You can change the inheritance at any time. You can swap the type of an instance at runtime.
@CodyGray Well, with stuff like Numpy, and libs that use GPUs, you kinda do. The native Python stuff is mostly handling the top level organization of the data, and compiled code handles the grunt work.
But even with pure Python, some stuff is relatively fast, eg list methods can internally loop at C speed, which is a lot faster than an explicit Python for loop. Which leads to the situation where the performance of Python code doesn't appear to conform to traditional big O analysis.
@PM2Ring Wait, wait. That last assertion doesn't follow. Big-O is still correct. A list method is still running a loop internally. You have to know what your code is actually doing in order to do the analysis. You can't just count statements or look for loops in your high-level language.
@MisterMiyagi Hrm... that sounds not great.
But still not convincing for why it cannot be a compiled language. All of that information is available ahead of time to the compiler, just as it's available to the runtime, which is itself compiled ahead of time.
Basically, we have two groups of compilers for Python: A) Those that add some sneaky restrictions which usually do not hurt. E.g. Cython has immutable classes and functions. B) Those that JIT to separate the ugly parts from the good ones. E.g. PyPy looks if you do evil stuff. But those are really top-of-the-line JITs (a large inspiration for Graal VM) and still run slower than languages made for compiling because there are so many escape hatches needed.
@CodyGray What I mean is that say you have 3 algorithms to perform some task, X, Y, Z. If you implement them in C, X is slower than Y which is slower than Z. But in Python, the nearest equivalents may have Z slower than X for typucal
Cython is seriously outdated, though. Its type system does not lend itself to doing interesting things, being basically sugar around C. For example, "templating" means that you predefine what variants of a type there are. There are no generics.
@CodyGray What I mean is that say you have 3 algorithms to perform some task, X, Y, Z. If you implement them in C, X is slower than Y which is slower than Z. But in Python, the nearest equivalents may have Z slower than X for typical data sizes of say a few hundred items, but X is slower than Z when you deal with a million items.
It drives people like me crazy, people who are used to looking at the implementation details and prefer to have that control.
@MisterMiyagi I see. Yeah, that doesn't sound too good.
It also sounds like it is a bit of a fork/modification of the language itself, which is sub-par.
To do it correctly, it needs to be exactly the same code that you can run in the standard Python interpreter as you would run through the ahead-of-time static compiler.
The relative execution speeds of algorithms implemented in CPython may be different to what one would expect from a simple analysis of the algorithms, and from experience with other languages. That's because Python provides many powerful functions and methods implemented in C that can operate on lists and other collections at close to the speed one would get in a fully-compiled language, so those operations run much faster than equivalent algorithms implemented "manually" with Python code.
Code that takes advantage of these tools can often outperform theoretically superior algorithms that …
There is a bit of a problem here due to Python by its nature not being used for all-out performance. That means the community lacks drive+knowledge to really tackle the problem consistently. Python compilers are usually made to solve problems of specific groups, and do not generalise well.
@MisterMiyagi Yeah, I guess that is really my question. In my mind, I don't see it as a technical problem/limitation, but rather a (A) limitation of vision, and (B) lack of resources.
I'm not sure if you're right about the lack of immutability posing insurmountable technical problems in terms of statically compiling Python.
But I certainly didn't know that was a language feature. And the thought of it does make me slightly uncomfortable...
Not sure if the problems are insurmountable. But I fell they are needless. Basically a lot of time is wasted teaching compilers tricks that they should not need in the first place.
@CodyGray I get that, and it did make me feel like I was losing a vital connection to the CPU when I first started with Python. Mind you, I had about 5 years of experience coding in assembler before I learned that C existed.
Even more than performance, one of my primary missions as a programmer is to figure out how to move as many potential errors as possible from runtime to compile time. In my ideal world, if the code compiles, it should be free of all but logic errors.
For example, if you look at PyPy that is basically (from very high up) a "regular" compiler plus an entire "does the user code do stupid" framework. Their limiting factor is the latter, not the former.
@CodyGray We have that one surprisingly well covered. Basically static analysis tools just assume you don't do stupid. Then Python is easy to check.
@CodyGray Good point. And I do miss that in Python, although as MisterMiyagi says, there are analysis tools that kind of address that defect. Of course, Python's data model and the whole "duck-typing" thing does make static code analysis much harder.
But I'm talking about insane stuff to move as many errors from runtime to compile time. Static bounds checking, for example. You don't represent months as an integer, because valid months are only from 1-12. A compiler won't catch out-of-range errors if you represent a month as an integer. That means you can end up with runtime out-of-range errors. That's bad.
Some of this is perhaps colored by the fact that I work on high-availability systems. Runtime errors are evil.
@CodyGray Yeah. As someone using these dark arts myself, I have to say it is surprisingly workable. Basically it forces you to have the ugly stuff encapsulated and well-tested. The user just sees some Java'esque, regularly-typed stuff.
@MisterMiyagi What is the advantage of this, over doing it the "right" way? C++ doesn't have reflection. I've never missed it. Even though I used to use it back when I did C#/VB.NET.
Basically, we have more power and flexibility behind the scenes. E.g. the metaclass stuff allows for some truly groundbreaking stuff. All of enums, abstract classes, protocols (structural typing), and type annotations run on metaclasses. I'm currently cooking up some metaclass-based concurrent error handling scheme.
Well, seeing how C++ templates are turing complete, there really isn't anything you are missing out on. ^^ But compared to the entire range of languages that use Generics, non-first-class types and such, there's a huge capability difference.
That would have been really useful about a year ago, when I had a really good algorithm developer working with me who knew Python but no other languages (since he wasn't trained as a programmer). His algorithm implementations were solid, but I had to port all of them to a real language to have any hope of efficiency. (Or running on embedded systems.)
About 4 months in, I persuaded him to learn C++. He never looked back. :-)
@CodyGray it's a well-developed library by now. Works nicely, but you often have to fiddle with it (like changing list literals to numpy arrays to help infer types)
But you're going to use it with your bottlenecks anyway...
Honestly, the major reason why I use Python is that I can collaborate with any imbecile and still figure out what's proper. Usually, that imbecile is me at 3 AM.
@MisterMiyagi I just don't buy that as an explanation, honestly. Even drunk me at 3 AM has no trouble writing correct C++ code. It's all what you get comfortable and familiar with.
Yup. They want Julia to be a migration path for those afflicted with MATLAB, which does make a lot of sense as a design goal in the abstract, but it means a lot of ugliness creeps in.
@Skyler TDD solves some subset of problems, but I'm not sure it really helps with readability/elegance.
@AndrasDeak Yeah, haven't kept up with modern MATLAB. Still stuck on version 2011b, which I use because I have no choice (legacy code + "programmers" who only speak MATLAB).
One of the things I've done at work is port numeric algorithms from MATLAB into C++, where I've witnessed anywhere from a 60 to 100 times performance increase. It's absurd, honestly.
turning a bowling game into 14 lines of very readable code with some other 1 line helper functions is pretty powerful imo, not useful in every context but quite elegant in some ways
@AndrasDeak That's what some MathWorks representative told me at a conference some time back. I asked him by what factor the code was improved. It wasn't 60-100x....
@CodyGray It's purely a personal impression, I admit. In my experience, beginners of Python do not have access to the advanced/evil stuff and thus tend to write boring, straightforward code. In other languages, macros/generics/templates is something you learn from day 2 already.
@MisterMiyagi Anyone who is teaching macros to budding C++ programmers is doing it wrong. There is pretty much a single valid use-case for macros in C++, and that is run-time asserts so you can get all kinds of juicy metadata automatically inserted. That should be handled by a library, freeing you from ever writing any macros yourself.
@CodyGray Every language has their own evil – macros are indeed not something I'd weight against C++. But take Rust for example. I really like that one, but they introduce Macros right at the start of the language documentation.
I can't really take Rust as an example, since I haven't learned it. I would like to, I think, but I just don't have the time. (This is unlike Go, which I have already decided I'm not especially interested in learning.)
@CodyGray Commas make tuples. The parentheses are only required for tuples in situations which would be ambiguous without them. So we can do stuff like a, b, c = 2, 3, 5
@AndrasDeak See, that's what I don't get. In what universe is that any more clear or readable than just using a temporary variable? It's too damn clever. You're trying too hard.
@AndrasDeak Uh, well, I do like classical music. But it's not something I listen to on a regular basis. Stravinsky is one of my favorite composers, for example.
@Noé W3Schools has a bad reputation on Stack Overflow. They have improved tremendously, but they're still not ideal. And they have wrong or misleading info regarding Python. Also see w3fools.com
FWIW, years ago the W3C requested that w3schools change their name because it was too close to W3C, and they didn't want people thinking that w3schools is somehow affiliated with or endorsed by the W3C. You may note that the w3schools site even looks similar to the W3C...
I got that W3C vs w3schools info from my xkcd buddy Tab Atkins, who is on the W3C CSS Working Group (as well as being a developer at Google). W3C didn't just ask once, they've asked repeatedly, to no avail, and they don't want to waste money taking it to court. I guess they also don't want the possibility of not winning the case.
@MisterMiyagi Yes, plenty of things fall out for free in the implementation of powerful features. I get that, obviously. What I take issue with is the claim that it is somehow more clear/obvious than simply using a temporary variable to swap a value.
It should be the default, though. You should have to explicitly indicate that a particular function is designed to allow overriding, not the other way around.
Some people like dense cryptic looking code. Especially if it's all packed into one line. This goes against Kernighan's maxim, and Python's philosophy of optimizing for readability.
It's technically useful if you have an API such as the one for regex. Then you first need to check whether you have a match before using the match in the block.
