My coding team has chosen implement a coding standard of using #property's for all instance ivars. For publicly facing things, we of course define them in our .h files, but for our private things, we define them in the .m file in an interface above our implementation.
Does it matter if I refer to them as self.myvar = whatever or as [self setMyvar:whatever]? It doesn't seem to matter at all to me, and there seems to be a great deal of mixing one way or the other in our code base.
self.myvar = whatever
is syntactic sugar for
[self setMyvar:whatever]
They're exactly the same thing. No difference at all.
As others have indicated, foo.bar and [foo bar] are equivalent (save for the additional type requirements on the former, but that is minor).
FWIW, our team decided to eschew the dot syntax completely. The motivation is to avoid ambiguity; a message send always looks like a message send and .s are always used to access structure members.
We also limit our use of #{} and #[] to the creation of collections only. All accesses are done via indexOfObject:, objectForKey:, etc...
As well, we use ARC everywhere save for a couple of border files that sit between ObjC and C++. And we have the static analyzer turned on for all DEBUG builds and all warnings are treated as hard errors. We've also turned on just about every compiler warning that is practical (there are some that simply aren't practical to use).
There is plenty of similar questions.
In our coding standards, we don't care about using dot notation or method to access the property. We even sometimes use dot notation for methods which are not formally declared as property because with library methods it's sometimes hard to know without checking the docs and it doesn't make a difference.
It never makes sense to forbid direct method calls (hard to enforce).
I saw coding standards forbidding the dot notation.
In general I tend to prefer dot notation because it enables me to split assignments into visually separated parts, e.g.
self.a = x;
against
[self setA:x];
The second just seems less readable to me but it's a matter of personal taste.
On the other hand, sometimes it's easier to use the method directly, e.g. when you have the object as an id and you would have to cast to use the dot notation.
I think that mixing both is a good solution. Choose the one that will increase the readibility at the given place.
self.myVar = x is actually compiled to [self setMyVar: x];. There's no run-time difference.
However; for ease of code readability, I'd advise sticking with one scheme or the other. If you've already had properties enforced, it'd be better to leave everything in the dot notation - if for no other reason than because this allows your code to be more easily searched.
Related
I see this recommended in the dart style guide, and copied in tons of tutorials and flutter source.
final foo = config.foo;
I don't understand it, how is this considered best practice when the readability is so poor? I have no clue what foo is here, surely final String foo = config.foo is preferable if we really want to use final?
This seems the equivalent to using var, which many consider a bad practice because it prevents the compiler from spotting errors and is less readable.
Where am I wrong?
In a lot of cases is does not really matter what type you are using as long the specific type can be statically determined by the compiler. When you are using var/final in Dart it is not that Dart does not know the type, it will just figure it out automatically based on the context. But the type must still be defined when the program are compiled so the types will never be dynamic based on runtime behavior. If you want truly dynamic types, you can use the dynamic keyword where you tell Dart "trust me, I know what I am doing with this types".
So types should still be defined where it matter most. This is e.g. for return and argument types for methods and class variables. The common factor for this types is that they are used to define the interface for using the method or class.
But when you are writing code inside a method, you are often not that interested in the specific types of variables used inside the method. Instead the focus should be the logic itself and you can often make it even more clear by using good describing variable names. As long the Dart analyzer can figure out the type, you will get autocomplete from your IDE and you can even still see the specific type from your IDE by e.g. Ctrl+Q in IntelliJ on the variable if you ends up in a situation where you want to know the type.
This is in particular the case when we are talking about the use of generics where it can be really tiresome to write the full specific type. Especially if you are using multiple generics inside each other like e.g. Map<String, List<String>>.
In my experience, Dart is really good to figure out very specific types and will complain loudly if your code cannot be determined statically. In the coming future, Dart will introduce non-null by default, which will make the Dart compiler and analyzer even more powerful since it will make sure your variable cannot be null unless this is something you specifically want and will make sure you are going to test for null when using methods which are specified to not expecting null.
About "Where am I wrong?". Well, a lot of languages have similar feature of var/final like Dart with the same design principle about the type should still be statically determined by a compiler or runtime. And even Java has introducing this feature. As a experienced Java and Dart programmer I have come to the conclusion for myself that typing inside methods are really not that important in a lot of cases as long I can still easily figure out the specific type by using an IDE when it really matters.
But it does make it more important to name your variables so they are clearly defining the purpose. But I am hoping you already are doing that. :)
I'm not sure if this is the right place to ask this, since it's not really a technical question but more a question of style and coding practices...
I've always ben a fan of using "const" to define variables that will not be changing throughout their lifetime, most especially when they are parameters to functions/methods. This probably stems from my history with C++, where objects could be passed by reference rather than by pointer, but you wanted to ensure that the original value wasn't accidentally altered, either by you or by someone else on your team who was working on the same code snippet.
When looking through the headers for both Objective-C in general and Cocos2d specifically, I've noticed that there is a noticeable lack of use of this item. Now, I'm not against developing code as quickly as possible, and leaving off constraints such as these leave the developer the option to modify values as their code develops and evolves, but there are some instances where I believe that this laxity does not belong.
For example, in Cocos2D/UIKit, the "UIFont fontWithName" method takes "(NSString *)" as the parameter for the font name: does this method really need to reserve the right to alter the original string that was passed in? I personally like to define constant strings as "const" items, and I don't like the necessity of casting these as non-"const" when calling these methods.
Enough proselytizing: My question - Is the direction now moving towards less well-defined interfaces and more towards "lazy references" (which I do not consider to be a derogative term)?
Thanks in advance for any feedback....
Const wouldn't mean anything for Objective C class pointers, because it would have to be overloaded in a very confusing way for Objective C types. This is because there's no way to mark a method as const, as there is in C++, so the compiler could never enforce it.
That said, at my old company, we did declare global string constants using something like:
NSString* const kMyCoolString = #"Hello, world!";
The point being that it at least couldn't be reassigned to something else.
The closest analog in Objective C/Cocoa/Foundation are mutable/immutable versions of data structures, which doesn't really help your case.
This question is specifically focused around static libraries / frameworks; in other words, code that other people will eventually touch.
I'm fairly well versed in properties, since I started iOS development when iOS 6 was released. I have used hidden properties declared in interface extensions to do all of my "private" property work, including using readonly on public facing properties I don't want others to modify and readwrite within interface extensions.
The important thing is that I do not want other people who are using these static libraries / frameworks to be accessing these properties if I don't allow it, nor writing these properties if I let them read it.
I've known for a while that they could theoretically create their own interface extension and make my readonly properties readwrite themselves, or guess the names of hidden properties.
If I want to prevent this, should I be using ivars with the #private tag with directly declared ivars? Are there potential downfalls to doing it this way? Does it actually get me an additional measure of security, or is it a red herring?
Under ARC the only mode supported by properties and not instance variables is copy - so if you need copy use a property.
If you declare your private instance variables in the #implementation section:
#implementation MyClass
{
// private instance vars
}
then it takes serious effort to access them from outside the class. As you say accessing a "private" property just takes guessing its name - or using the library calls which tell you.
Is it worth it for security? YMMV. But its a good coding practice regardless.
Addendum
As the comment trail shows there has been much discussion over my use of serious effort.
First let's be clear: Objective-C is in the C family of languages, they all allow the programmer to just about anything they choose while staying within the language[*] - these are not the languages of choice if you want strong typing, access restrictions, etc., etc. within your code.
Second, "effort" is not an absolute measure! So maybe I should have chosen the word "obvious" to qualify it rather than "serious". To access a private property just requires the use of a standard method call where the object has type id - there is little clue in the code that the method being called is hidden. To access a private variable requires either an API call (a runtime function or KVC call) or some pointer manipulation - the resultant code looks nothing like a standard variable assignment. So its more obvious.
That said, apart from uses requiring copy, under ARC there is no good reason to use a private property when a private instance variable will do. For a private variable fred compare:
self.fred = 42; // property access, may involve a call (if not optimised out)
_fred = 42; // common way to bypass the accessors and get at the underlying var
fred = 42; // direct access
Take your pick, there is no right answer, but there isn't a wrong one either - this is the realm of opinion (and that is of course an opinion ;-)). I would often pick the last one, private variable - clean & simple. However #RobNapier in his answer prefers the use of properties.
[*] Note: once you consider linking to external code, say written in assembler, all bets are of in any language. At that point you have to look at the "hardware" (real or virtual) and/or "OS" to provide protection.
You should use private ("hidden") properties here. There is no "security" risk. The "attacker" in this scenario is the caller. The caller has complete access to all memory in the process. She can access anything in your framework she wants and there is absolutely nothing you can do to stop that (nor should you). This is true in any language. You can bypass "private:" designations in C++ as well if you know what you're doing. It's all just memory at the end of the day.
It is not your job to protect yourself or your framework from the caller. You both have the same goal: correct program behavior. Your goal is to protect callers from themselves. Make it difficult for them to use your framework incorrectly and easy to use it correctly.
So, you should use the tool that leads to the most correct code. And that tool is properties, and avoiding directly ivar access except in init and dealloc.
I have been reading up on the c++ auto_ptr and unique_ptr and stuff and thought to try and use them in a class I am playing with... but I was having trouble getting it to work...
How would I convert these pointers to auto pointers or some equivalent so the deletion of the pointers is handled automatically?
Header - http://ideone.com/Z9bc5
Body - http://ideone.com/WfwBY
At the moment it is working using normal pointers but I sometimes get a access violation error. I am pretty sure I know what it causing it.. but the "best" way might be to use the automatic deletion stuff recently added to c++11?
Thanks in advance.
Don't use auto_ptr. Try one of unique_ptr or shared_ptr. Here's Sutter explaining when to use which:
When in doubt, prefer unique_ptr by default, and you can always later move-convert to shared_ptr if you need it. If you know from the start you need shared ownership, however, go directly to shared_ptr via make_shared (see #2 below).
Also from his blog-post:
3. What’s the deal with auto_ptr?
auto_ptr is most charitably characterized as a valiant attempt to
create a unique_ptr before C++ had move semantics.
auto_ptr is now deprecated, and should not be used in new code. When
you get a chance, try doing a global search-and-replace of auto_ptr to
unique_ptr in your code base; the vast majority of uses will work the
same, and it might expose (as a compile-time error) or fix (silently)
a bug or two you didn’t know you had.
So, your member declarations change from:
sf::Texture * tSpriteSheet;
to:
std::unique_ptr<sf::Texture> tSpriteSheet;
As for member functions which return a raw pointer you have but the obvious choice: You cannot return a unique_ptr if the class is not movable. So, you can either:
Keep the signature as-is
Return a const& unique_ptr<T>
Return a reference to the object
Choose the one that suits your needs the best.
The problem is whether an instance method should in anyway alter the object that contains the method or should it return a new instance? I'm new to F# and the concept of full mmutability that is suggested for F#.
Just using psuedo code for now unless I need to be more specific.
First thought is just add the message to the message list on the object:
class Something
ctr(messages)
_messages.Add(messages)
AddMessage(message)
_messages.Add(message)
Second is to construct a new list that joins the old list and the new message. Then I would create a new instance altogther and send back.
class Something
ctr(messages)
_messages.Add(messages)
AddMessage(message)
newMessageList = _messages.Join(message)
return new Something(newMessageList)
Am I overthinking immutability?
In my opinion, the answer depends on your requirements. The immutable style is probably more idiomatic, and would be a sensible default. However, one nice thing about F# is that you can choose what to do based on your needs; there's nothing inherently wrong with code that uses mutation. Here are some things to consider:
Sometimes the mutable approach leads to better performance, particularly when used in a single-threaded context (but make sure to measure realistic scenarios to be sure!)
Sometimes the immutable approach lends itself better to use in multi-threaded scenarios
Sometimes you want to interface with libraries that are easier to use with imperitave code (e.g. an API taking a System.Action<_>).
Are you working on a team? If so, are they experienced C# developers? Experienced F# developers? What kind of code would they find easiest to read (perhaps the mutable style)? What kind of code will you find easiest to maintain (probably the immutable style)?
Are you just doing this as an exercise? Then practicing the immutable style may be worthwhile.
Stepping back even further, there are a few other points to consider:
Do you really even need an instance method? Often, using a let-bound function in a module is more idiomatic.
Do you really even need a new nominal type for what you're doing? If it's just a thin wrapper around a list, you might consider just using lists directly.
As you are doing "class based" programming which is one of the way (rather unfortunate) to do object oriented programming, you would be doing in place state modification rather than returning a new state (as that's what would be expected when you are doing OO).
In case you really want to go towards immutability then I would suggest you need to use more FP concepts like Modules, Functions (not methods which have you have in class based programming), recursive data types etc.
My answer is way too general and the appropriate answer lies in the fact that how this class of your will fit in the big picture of your application design.