Design by Contract in Swift - ios

Does Swift provide a native Design by Contract support? I understand that it can be done during runtime through assertions, but could it be done during compile time? Or, are there any external plugins/libraries that do this?
EDIT
By saying "during compile time Design by Contract", I do not mean the library to be an all powerful static analyser that C# has. It would be enough for me if it is something like the one that iContract provides for Java. Let us look at an example:
A DBC code for the square root evaluation in Java using iContract could be written as :
/**
* #pre f >= 0.0
* #post Math.abs((return * return) - f) < 0.001
*/
public float sqrt(float f) { ... }
Now, this keeps my contract as a part of my API specification rather than a part of its implementation which I believe is a cleaner way. The caller will know what his responsibilities are and the callee is setting its expectation, all in albeit clearer manner. Do we have something like this in Swift?

TL;DR
As #Tommy points out in the comments under your question, it would appear that the plain & simple answer to your question is "No, compile time DbC is not currently a feature of Swift".
What's built in right now?
For built-in support for this type of design strategy, you currently have to look at the runtime I'm afraid. Swift appears to prefer runtime assertions for enforcing preconditions currently, although the language seems generally to be putting more emphasis on safety at compile time (more on this below). The global functions assert, assertionFailure, precondition and preconditionFailure are designed to be sprinkled liberally throughout code without impacting release build performance.
Unit tests are, of course, another strategy for checking that API contracts are fulfilled, but these must be thought of and implemented manually, and so are error prone.
Something else that is perhaps interesting to note is that amongst the better documentation comment support of Swift 2, "requires", "precondition" and "postcondition" are recognised markup keywords, such that they are displayed prominently in quick help documentation:
/// - precondition: f >= 0.0
/// - postcondition: abs((return * return) - f) < 0.001
/// - returns: The square root of `f`.
func sqrt(f: Float) -> Float { ... }
So does this emphasis on being able to provide good documentation for API contracts mean that the Swift development team clearly cares about it, and this is a stop-gap until they incorporate something into the syntax in the future, or does it mean that they think this sort of information belongs in the documentation? Pointless postulation, perhaps. Regardless, despite the fact it's not proper DbC, I think it's a handy thing to be aware of right now.
What can I do about it now?
With Objective-C, macros could be used to essentially implement basic DbC, however the lack of macros in Swift means you would have to resort to some kind of function/generics-based wrapper, which I think would look like a really awkward bodge.
Xcode's support for adding custom scripts to a target's build phases – as suggested by #JonShier in the comments – is perhaps the closest you will get to useful & automatic DbC without waiting for the language to (maybe / maybe not) introduce such a feature. With the aforementioned documentation markup keywords, a script that analyses documentation comments to build unit tests could even be incorporated retrospectively to projects with only a small amount of learning/effort on the part of the user. As you say, I think this could make a very interesting project!
Will it be a built-in feature in the future?
It is not clear whether or not native DbC might be incorporated into Swift in the future. Arguably, it is a feature that is well suited to the mission of the Swift language, which is to say that it promotes safer code and reduced risk of runtime errors. Should it become a part of the language, I would suggest that we would be more likely to see them appear as declaration attributes than as interpreted comment markup, for example:
#contract(
precondition = f >= 0.0,
postcondition = abs((return * return) - f) < 0.001
)
func sqrt(f: Float) -> Float { ... }
(But that is just speculation, and of no use to us right now!)
From what I know of the topic, compile-time DbC can be a very complex problem. But who knows... work on the Clang Static Analyzer has certainly shown that there is an underlying desire to drag identification of runtime bugs back to compile time. Perhaps this is the perfect problem to put a Swift static analyser to work on in the future?

I'm not if this is what you're looking for but here is a suggestion you could try maybe.
If you want to define a protocol where you can define the signature of the sqrt function and leave the implementation for other classes or structs to implement at a later point you could do something like the code below:
Note: the the sqrtf is just using the system implementation here.
public protocol Math {
func sqrtf(f: Float) -> Float
}
struct NativeMath: Math {
func sqrtf(f: Float) -> Float {
return sqrt(f)
}
}
println(NativeMath().sqrtf(2))

Related

Compilation error due to ambiguity in definition of Window object in Zbar and Xlib [duplicate]

I have heard using namespace std; is bad practice, and that I should use std::cout and std::cin directly instead.
Why is this? Does it risk declaring variables that share the same name as something in the std namespace?
Consider two libraries called Foo and Bar:
using namespace foo;
using namespace bar;
Everything works fine, and you can call Blah() from Foo and Quux() from Bar without problems. But one day you upgrade to a new version of Foo 2.0, which now offers a function called Quux(). Now you've got a conflict: Both Foo 2.0 and Bar import Quux() into your global namespace. This is going to take some effort to fix, especially if the function parameters happen to match.
If you had used foo::Blah() and bar::Quux(), then the introduction of foo::Quux() would have been a non-event.
It can get worse than what Greg wrote!
Library Foo 2.0 could introduce a function, Quux(), that is an unambiguously better match for some of your calls to Quux() than the bar::Quux() your code called for years. Then your code still compiles, but it silently calls the wrong function and does god-knows-what. That's about as bad as things can get.
Keep in mind that the std namespace has tons of identifiers, many of which are very common ones (think list, sort, string, iterator, etc.) which are very likely to appear in other code, too.
If you consider this unlikely: There was a question asked here on Stack Overflow where pretty much exactly this happened (wrong function called due to omitted std:: prefix) about half a year after I gave this answer. Here is another, more recent example of such a question.
So this is a real problem.
Here's one more data point: Many, many years ago, I also used to find it annoying having to prefix everything from the standard library with std::. Then I worked in a project where it was decided at the start that both using directives and declarations are banned except for function scopes. Guess what? It took most of us very few weeks to get used to writing the prefix, and after a few more weeks most of us even agreed that it actually made the code more readable. There's a reason for that: Whether you like shorter or longer prose is subjective, but the prefixes objectively add clarity to the code. Not only the compiler, but you, too, find it easier to see which identifier is referred to.
In a decade, that project grew to have several million lines of code. Since these discussions come up again and again, I once was curious how often the (allowed) function-scope using actually was used in the project. I grep'd the sources for it and only found one or two dozen places where it was used. To me this indicates that, once tried, developers don't find std:: painful enough to employ using directives even once every 100 kLoC even where it was allowed to be used.
Bottom line: Explicitly prefixing everything doesn't do any harm, takes very little getting used to, and has objective advantages. In particular, it makes the code easier to interpret by the compiler and by human readers — and that should probably be the main goal when writing code.
The problem with putting using namespace in the header files of your classes is that it forces anyone who wants to use your classes (by including your header files) to also be 'using' (i.e. seeing everything in) those other namespaces.
However, you may feel free to put a using statement in your (private) *.cpp files.
Beware that some people disagree with my saying "feel free" like this -- because although a using statement in a cpp file is better than in a header (because it doesn't affect people who include your header file), they think it's still not good (because depending on the code it could make the implementation of the class more difficult to maintain). This C++ Super-FAQ entry says,
The using-directive exists for legacy C++ code and to ease the transition to namespaces, but you probably shouldn’t use it on a regular basis, at least not in your new C++ code.
The FAQ suggests two alternatives:
A using-declaration:
using std::cout; // a using-declaration lets you use cout without qualification
cout << "Values:";
Just typing std::
std::cout << "Values:";
I recently ran into a complaint about Visual Studio 2010. It turned out that pretty much all the source files had these two lines:
using namespace std;
using namespace boost;
A lot of Boost features are going into the C++0x standard, and Visual Studio 2010 has a lot of C++0x features, so suddenly these programs were not compiling.
Therefore, avoiding using namespace X; is a form of future-proofing, a way of making sure a change to the libraries and/or header files in use is not going to break a program.
Short version: don't use global using declarations or directives in header files. Feel free to use them in implementation files. Here's what Herb Sutter and Andrei Alexandrescu have to say about this issue in C++ Coding Standards (bolding for emphasis is mine):
Summary
Namespace usings are for your convenience, not for you to inflict on others: Never write a using declaration or a using directive before an #include directive.
Corollary: In header files, don’t write namespace-level using directives or using declarations; instead, explicitly namespace-qualify all names. (The second rule follows from the first, because headers can never know what other header #includes might appear after them.)
Discussion
In short: You can and should use namespace using declarations and directives liberally in your implementation files after #include directives and feel good about it. Despite repeated assertions to the contrary, namespace using declarations and directives are not evil and they do not defeat the purpose of namespaces. Rather, they are what make namespaces usable.
One shouldn't use the using directive at the global scope, especially in headers. However, there are situations where it is appropriate even in a header file:
template <typename FloatType> inline
FloatType compute_something(FloatType x)
{
using namespace std; // No problem since scope is limited
return exp(x) * (sin(x) - cos(x * 2) + sin(x * 3) - cos(x * 4));
}
This is better than explicit qualification (std::sin, std::cos...), because it is shorter and has the ability to work with user defined floating point types (via argument-dependent lookup (ADL)).
Do not use it globally
It is considered "bad" only when used globally. Because:
You clutter the namespace you are programming in.
Readers will have difficulty seeing where a particular identifier comes from, when you use many using namespace xyz;.
Whatever is true for other readers of your source code is even more true for the most frequent reader of it: yourself. Come back in a year or two and take a look...
If you only talk about using namespace std; you might not be aware of all the stuff you grab -- and when you add another #include or move to a new C++ revision you might get name conflicts you were not aware of.
You may use it locally
Go ahead and use it locally (almost) freely. This, of course, prevents you from repetition of std:: -- and repetition is also bad.
An idiom for using it locally
In C++03 there was an idiom -- boilerplate code -- for implementing a swap function for your classes. It was suggested that you actually use a local using namespace std; -- or at least using std::swap;:
class Thing {
int value_;
Child child_;
public:
// ...
friend void swap(Thing &a, Thing &b);
};
void swap(Thing &a, Thing &b) {
using namespace std; // make `std::swap` available
// swap all members
swap(a.value_, b.value_); // `std::stwap(int, int)`
swap(a.child_, b.child_); // `swap(Child&,Child&)` or `std::swap(...)`
}
This does the following magic:
The compiler will choose the std::swap for value_, i.e. void std::swap(int, int).
If you have an overload void swap(Child&, Child&) implemented the compiler will choose it.
If you do not have that overload the compiler will use void std::swap(Child&,Child&) and try its best swapping these.
With C++11 there is no reason to use this pattern any more. The implementation of std::swap was changed to find a potential overload and choose it.
If you import the right header files you suddenly have names like hex, left, plus or count in your global scope. This might be surprising if you are not aware that std:: contains these names. If you also try to use these names locally it can lead to quite some confusion.
If all the standard stuff is in its own namespace you don't have to worry about name collisions with your code or other libraries.
Another reason is surprise.
If I see cout << blah, instead of std::cout << blah I think: What is this cout? Is it the normal cout? Is it something special?
Experienced programmers use whatever solves their problems and avoid whatever creates new problems, and they avoid header-file-level using-directives for this exact reason.
Experienced programmers also try to avoid full qualification of names inside their source files. A minor reason for this is that it's not elegant to write more code when less code is sufficient unless there are good reasons. A major reason for this is turning off argument-dependent lookup (ADL).
What are these good reasons? Sometimes programmers explicitly want to turn off ADL, other times they want to disambiguate.
So the following are OK:
Function-level using-directives and using-declarations inside functions' implementations
Source-file-level using-declarations inside source files
(Sometimes) source-file-level using-directives
I agree that it should not be used globally, but it's not so evil to use locally, like in a namespace. Here's an example from "The C++ Programming Language":
namespace My_lib {
using namespace His_lib; // Everything from His_lib
using namespace Her_lib; // Everything from Her_lib
using His_lib::String; // Resolve potential clash in favor of His_lib
using Her_lib::Vector; // Resolve potential clash in favor of Her_lib
}
In this example, we resolved potential name clashes and ambiguities arising from their composition.
Names explicitly declared there (including names declared by using-declarations like His_lib::String) take priority over names made accessible in another scope by a using-directive (using namespace Her_lib).
I also consider it a bad practice. Why? Just one day I thought that the function of a namespace is to divide stuff, so I shouldn't spoil it with throwing everything into one global bag.
However, if I often use 'cout' and 'cin', I write: using std::cout; using std::cin; in the .cpp file (never in the header file as it propagates with #include). I think that no one sane will ever name a stream cout or cin. ;)
It's nice to see code and know what it does. If I see std::cout I know that's the cout stream of the std library. If I see cout then I don't know. It could be the cout stream of the std library. Or there could be an int cout = 0; ten lines higher in the same function. Or a static variable named cout in that file. It could be anything.
Now take a million line code base, which isn't particularly big, and you're searching for a bug, which means you know there is one line in this one million lines that doesn't do what it is supposed to do. cout << 1; could read a static int named cout, shift it to the left by one bit, and throw away the result. Looking for a bug, I'd have to check that. Can you see how I really really prefer to see std::cout?
It's one of these things that seem a really good idea if you are a teacher and never had to write and maintain any code for a living. I love seeing code where (1) I know what it does; and, (2) I'm confident that the person writing it knew what it does.
It's all about managing complexity. Using the namespace will pull things in that you don't want, and thus possibly make it harder to debug (I say possibly). Using std:: all over the place is harder to read (more text and all that).
Horses for courses - manage your complexity how you best can and feel able.
A concrete example to clarify the concern. Imagine you have a situation where you have two libraries, foo and bar, each with their own namespace:
namespace foo {
void a(float) { /* Does something */ }
}
namespace bar {
...
}
Now let's say you use foo and bar together in your own program as follows:
using namespace foo;
using namespace bar;
void main() {
a(42);
}
At this point everything is fine. When you run your program it 'Does something'. But later you update bar and let's say it has changed to be like:
namespace bar {
void a(float) { /* Does something completely different */ }
}
At this point you'll get a compiler error:
using namespace foo;
using namespace bar;
void main() {
a(42); // error: call to 'a' is ambiguous, should be foo::a(42)
}
So you'll need to do some maintenance to clarify that 'a' meant foo::a. That's undesirable, but fortunately it is pretty easy (just add foo:: in front of all calls to a that the compiler marks as ambiguous).
But imagine an alternative scenario where bar changed instead to look like this instead:
namespace bar {
void a(int) { /* Does something completely different */ }
}
At this point your call to a(42) suddenly binds to bar::a instead of foo::a and instead of doing 'something' it does 'something completely different'. No compiler warning or anything. Your program just silently starts doing something completely different than before.
When you use a namespace you're risking a scenario like this, which is why people are uncomfortable using namespaces. The more things in a namespace, the greater the risk of conflict, so people might be even more uncomfortable using namespace std (due to the number of things in that namespace) than other namespaces.
Ultimately this is a trade-off between writability vs. reliability/maintainability. Readability may factor in also, but I could see arguments for that going either way. Normally I would say reliability and maintainability are more important, but in this case you'll constantly pay the writability cost for an fairly rare reliability/maintainability impact. The 'best' trade-off will determine on your project and your priorities.
Consider
// myHeader.h
#include <sstream>
using namespace std;
// someoneElses.cpp/h
#include "myHeader.h"
class stringstream { // Uh oh
};
Note that this is a simple example. If you have files with 20 includes and other imports, you'll have a ton of dependencies to go through to figure out the problem. The worse thing about it is that you can get unrelated errors in other modules depending on the definitions that conflict.
It's not horrible, but you'll save yourself headaches by not using it in header files or the global namespace. It's probably all right to do it in very limited scopes, but I've never had a problem typing the extra five characters to clarify where my functions are coming from.
You need to be able to read code written by people who have different style and best practices opinions than you.
If you're only using cout, nobody gets confused. But when you have lots of namespaces flying around and you see this class and you aren't exactly sure what it does, having the namespace explicit acts as a comment of sorts. You can see at first glance, "oh, this is a filesystem operation" or "that's doing network stuff".
Using many namespaces at the same time is obviously a recipe for disaster, but using JUST namespace std and only namespace std is not that big of a deal in my opinion because redefinition can only occur by your own code...
So just consider them functions as reserved names like "int" or "class" and that is it.
People should stop being so anal about it. Your teacher was right all along. Just use ONE namespace; that is the whole point of using namespaces the first place. You are not supposed to use more than one at the same time. Unless it is your own. So again, redefinition will not happen.
I agree with the others here, but I would like to address the concerns regarding readability - you can avoid all of that by simply using typedefs at the top of your file, function or class declaration.
I usually use it in my class declaration as methods in a class tend to deal with similar data types (the members) and a typedef is an opportunity to assign a name that is meaningful in the context of the class. This actually aids readability in the definitions of the class methods.
// Header
class File
{
typedef std::vector<std::string> Lines;
Lines ReadLines();
}
and in the implementation:
// .cpp
Lines File::ReadLines()
{
Lines lines;
// Get them...
return lines;
}
as opposed to:
// .cpp
vector<string> File::ReadLines()
{
vector<string> lines;
// Get them...
return lines;
}
or:
// .cpp
std::vector<std::string> File::ReadLines()
{
std::vector<std::string> lines;
// Get them...
return lines;
}
A namespace is a named scope. Namespaces are used to group related declarations and to keep separate
items separate. For example, two separately developed libraries may use the same name to refer to different
items, but a user can still use both:
namespace Mylib{
template<class T> class Stack{ /* ... */ };
// ...
}
namespace Yourlib{
class Stack{ /* ... */ };
// ...
}
void f(int max) {
Mylib::Stack<int> s1(max); // Use my stack
Yourlib::Stack s2(max); // Use your stack
// ...
}
Repeating a namespace name can be a distraction for both readers and writers. Consequently, it is possible
to state that names from a particular namespace are available without explicit qualification. For example:
void f(int max) {
using namespace Mylib; // Make names from Mylib accessible
Stack<int> s1(max); // Use my stack
Yourlib::Stack s2(max); // Use your stack
// ...
}
Namespaces provide a powerful tool for the management of different libraries and of different versions of code. In particular, they offer the programmer alternatives of how explicit to make a reference to a nonlocal name.
Source: An Overview of the C++ Programming Language
by Bjarne Stroustrup
An example where using namespace std throws a compilation error because of the ambiguity of count, which is also a function in algorithm library.
#include <iostream>
#include <algorithm>
using namespace std;
int count = 1;
int main() {
cout << count << endl;
}
It doesn't make your software or project performance worse. The inclusion of the namespace at the beginning of your source code isn't bad. The inclusion of the using namespace std instruction varies according to your needs and the way you are developing the software or project.
The namespace std contains the C++ standard functions and variables. This namespace is useful when you often would use the C++ standard functions.
As is mentioned in this page:
The statement using namespace std is generally considered bad
practice. The alternative to this statement is to specify the
namespace to which the identifier belongs using the scope operator(::)
each time we declare a type.
And see this opinion:
There is no problem using "using namespace std" in your source file
when you make heavy use of the namespace and know for sure that
nothing will collide.
Some people had said that is a bad practice to include the using namespace std in your source files because you're invoking from that namespace all the functions and variables. When you would like to define a new function with the same name as another function contained in the namespace std you would overload the function and it could produce problems due to compile or execute. It will not compile or executing as you expect.
As is mentioned in this page:
Although the statement saves us from typing std:: whenever
we wish to access a class or type defined in the std namespace, it
imports the entirety of the std namespace into the current namespace
of the program. Let us take a few examples to understand why this
might not be such a good thing
...
Now at a later stage of development, we wish to use another version of
cout that is custom implemented in some library called “foo” (for
example)
...
Notice how there is an ambiguity, to which library does cout point to?
The compiler may detect this and not compile the program. In the worst
case, the program may still compile but call the wrong function, since
we never specified to which namespace the identifier belonged.
It's case by case. We want to minimize the "total cost of ownership" of the software over its lifespan. Stating "using namespace std" has some costs, but not using it also has a cost in legibility.
People correctly point out that when using it, when the standard library introduces new symbols and definitions, your code ceases to compile, and you may be forced to rename variables. And yet this is probably good long-term, since future maintainers will be momentarily confused or distracted if you're using a keyword for some surprising purpose.
You don't want to have a template called vector, say, which isn't the vector known by everyone else. And the number of new definitions thus introduced in the C++ library is small enough it may simply not come up. There is a cost to having to do this kind of change, but the cost is not high and is offset by the clarity gained by not using std symbol names for other purposes.
Given the number of classes, variables, and functions, stating std:: on every one might fluff up your code by 50% and make it harder to get your head around. An algorithm or step in a method that could be taken in on one screenful of code now requires scrolling back and forth to follow. This is a real cost. Arguably it may not be a high cost, but people who deny it even exists are inexperienced, dogmatic, or simply wrong.
I'd offer the following rules:
std is different from all other libraries. It is the one library everyone basically needs to know, and in my view is best thought of as part of the language. Generally speaking there is an excellent case for using namespace std even if there isn't for other libraries.
Never force the decision onto the author of a compilation unit (a .cpp file) by putting this using in a header. Always defer the decision to the compilation unit author. Even in a project that has decided to use using namespace std everywhere may fine a few modules that are best handled as exceptions to that rule.
Even though the namespace feature lets you have many modules with symbols defined the same, it's going to be confusing to do so. Keep the names different to the extent possible. Even if not using the namespace feature, if you have a class named foo and std introduces a class named foo, it's probably better long-run to rename your class anyway.
An alternative to using namespaces is to manually namespace symbols by prefixing them. I have two libraries I've used for decades, both starting as C libraries, actually, where every symbol is prefixed with "AK" or "SCWin". Generally speaking, this is like avoiding the "using" construct, but you don't write the twin colons. AK::foo() is instead AKFoo(). It makes code 5-10% denser and less verbose, and the only downside is that you'll be in big trouble if you have to use two such libraries that have the same prefixing. Note the X Window libraries are excellent in this regard, except they forgot to do so with a few #defines: TRUE and FALSE should have been XTRUE and XFALSE, and this set up a namespace clash with Sybase or Oracle that likewise used TRUE and FALSE with different values! (ASCII 0 and 1 in the case of the database!) One special advantage of this is that it applies seemlessly to preprocessor definitions, whereas the C++ using/namespace system doesn't handle them. A nice benefit of this is that it gives an organic slope from being part of a project to eventually being a library. In a large application of mine, all window classes are prefixed Win, all signal-processing modules Mod, and so on. There's little chance of any of these being reused so there's no practical benefit to making each group into a library, but it makes obvious in a few seconds how the project breaks into sub-projects.
I agree with others – it is asking for name clashes, ambiguities and then the fact is it is less explicit. While I can see the use of using, my personal preference is to limit it. I would also strongly consider what some others pointed out:
If you want to find a function name that might be a fairly common name, but you only want to find it in the std namespace (or the reverse – you want to change all calls that are not in namespace std, namespace X, ...), then how do you propose to do this?
You could write a program to do it, but wouldn't it be better to spend time working on your project itself rather than writing a program to maintain your project?
Personally, I actually don't mind the std:: prefix. I like the look more than not having it. I don't know if that is because it is explicit and says to me "this isn't my code... I am using the standard library" or if it is something else, but I think it looks nicer. This might be odd given that I only recently got into C++ (used and still do C and other languages for much longer and C is my favourite language of all time, right above assembly).
There is one other thing although it is somewhat related to the above and what others point out. While this might be bad practise, I sometimes reserve std::name for the standard library version and name for program-specific implementation. Yes, indeed this could bite you and bite you hard, but it all comes down to that I started this project from scratch, and I'm the only programmer for it. Example: I overload std::string and call it string. I have helpful additions. I did it in part because of my C and Unix (+ Linux) tendency towards lower-case names.
Besides that, you can have namespace aliases. Here is an example of where it is useful that might not have been referred to. I use the C++11 standard and specifically with libstdc++. Well, it doesn't have complete std::regex support. Sure, it compiles, but it throws an exception along the lines of it being an error on the programmer's end. But it is lack of implementation.
So here's how I solved it. Install Boost's regex, and link it in. Then, I do the following so that when libstdc++ has it implemented entirely, I need only remove this block and the code remains the same:
namespace std
{
using boost::regex;
using boost::regex_error;
using boost::regex_replace;
using boost::regex_search;
using boost::regex_match;
using boost::smatch;
namespace regex_constants = boost::regex_constants;
}
I won't argue on whether that is a bad idea or not. I will however argue that it keeps it clean for my project and at the same time makes it specific: True, I have to use Boost, but I'm using it like the libstdc++ will eventually have it. Yes, starting your own project and starting with a standard (...) at the very beginning goes a very long way with helping maintenance, development and everything involved with the project!
Just to clarify something: I don't actually think it is a good idea to use a name of a class/whatever in the STL deliberately and more specifically in place of. The string is the exception (ignore the first, above, or second here, pun if you must) for me as I didn't like the idea of 'String'.
As it is, I am still very biased towards C and biased against C++. Sparing details, much of what I work on fits C more (but it was a good exercise and a good way to make myself a. learn another language and b. try not be less biased against object/classes/etc which is maybe better stated as less closed-minded, less arrogant, and more accepting.). But what is useful is what some already suggested: I do indeed use list (it is fairly generic, is it not ?), and sort (same thing) to name two that would cause a name clash if I were to do using namespace std;, and so to that end I prefer being specific, in control and knowing that if I intend it to be the standard use then I will have to specify it. Put simply: no assuming allowed.
And as for making Boost's regex part of std. I do that for future integration and – again, I admit fully this is bias - I don't think it is as ugly as boost::regex:: .... Indeed, that is another thing for me. There are many things in C++ that I still have yet to come to fully accept in looks and methods (another example: variadic templates versus var arguments [though I admit variadic templates are very very useful!]). Even those that I do accept it was difficult, and I still have issues with them.
From my experiences, if you have multiple libraries that uses say, cout, but for a different purpose you may use the wrong cout.
For example, if I type in, using namespace std; and using namespace otherlib; and type just cout (which happens to be in both), rather than std::cout (or 'otherlib::cout'), you might use the wrong one, and get errors. It's much more effective and efficient to use std::cout.
I do not think it is necessarily bad practice under all conditions, but you need to be careful when you use it. If you're writing a library, you probably should use the scope resolution operators with the namespace to keep your library from butting heads with other libraries. For application level code, I don't see anything wrong with it.
With unqualified imported identifiers you need external search tools like grep to find out where identifiers are declared. This makes reasoning about program correctness harder.
This is a bad practice, often known as global namespace pollution. Problems may occur when more than one namespace has the same function name with signature, then it will be ambiguous for the compiler to decide which one to call and this all can be avoided when you are specifying the namespace with your function call like std::cout . Hope this helps. :)
"Why is 'using namespace std;' considered a bad practice in C++?"
I put it the other way around: Why is typing five extra characters considered cumbersome by some?
Consider e.g. writing a piece of numerical software. Why would I even consider polluting my global namespace by cutting general "std::vector" down to "vector" when "vector" is one of the problem domain's most important concepts?
To answer your question I look at it this way practically: a lot of programmers (not all) invoke namespace std. Therefore one should be in the habit of NOT using things that impinge or use the same names as what is in the namespace std. That is a great deal granted, but not so much compared to the number of possible coherent words and pseudonyms that can be come up with strictly speaking.
I mean really... saying "don't rely on this being present" is just setting you up to rely on it NOT being present. You are constantly going to have issues borrowing code snippets and constantly repairing them. Just keep your user-defined and borrowed stuff in limited scope as they should be and be VERY sparing with globals (honestly globals should almost always be a last resort for purposes of "compile now, sanity later"). Truly I think it is bad advice from your teacher because using std will work for both "cout" and "std::cout" but NOT using std will only work for "std::cout". You will not always be fortunate enough to write all your own code.
NOTE: Don't focus too much on efficiency issues until you actually learn a little about how compilers work. With a little experience coding you don't have to learn that much about them before you realize how much they are able to generalize good code into something something simple. Every bit as simple as if you wrote the whole thing in C. Good code is only as complex as it needs to be.

Checklist for migrating to idiomatic Swift 2 (AKA where is the Swift 2 transition guide)?

I've been trying to locate a transition guide for Swift 2, in particular things developers should be aware of when migrating Swift 1/1.2 codebases over to Swift 2. Obviously you have the migration assistant in Xcode, but that only really covers the donkey work and not the stuff that requires a bit more intelligent thought.
Based on the resources I was able to find on Swift 2, I've put together the following checklist:
try/catch/throw error handling - to be used for recoverable errors; revise error handling code accordingly. In particular, check all uses of NSError and calling back to delegates to report recoverable errors.
Use enums conforming to ErrorType to define your own meaningful errors.
Use #available for accessing newer platform APIs - check API use against app Deployment Target and revise accordingly
protocol extensions - move as much code as possible into these to aid re-use. In particular refactor Global Functions into protocol extensions.
nullability annotations & generics - remove redundant optional bindings and type castings
Use do { } to control scope and free large resources early
Move old do { ... } while loops to repeat { } (to remove ambiguity and improve readability)
Use guard to return early and avoid excessive indentation
Use defer for cleanup code like closing files etc.
Use Option Sets rather than OR-ing values together (e.g. viewAnimationOptions = [.Repeat, .CurveEaseIn, .TransitionCurlUp])
Review public accessor specifiers which were previously only required to support testing. Use #testable and import MyApp instead.
Move single-case switch statements to the new if case .MyEnumCase(let value) = bar() where value != 42 { doThing(value) }
Use "for ... in" filtering to clean up for loops containing if filtering statements e.g. for value in mySequence where value != "" { }
native support for C function pointers - provide using closures or global functions (do not capture local context when doing so)
fix any new let/var warnings
fix any unused variable warnings
Failable initializers can now return nil before calling super.init - remove any previous workarounds required. Designated initializers still have to initialize all stored properties before returning nil however.
Sources:
https://developer.apple.com/swift/blog/?id=29
https://developer.apple.com/swift/
https://developer.apple.com/library/prerelease/ios/releasenotes/DeveloperTools/RN-Xcode/Chapters/xc7_release_notes.html#//apple_ref/doc/uid/TP40001051-CH5-SW1
https://developer.apple.com/videos/wwdc/2015/?id=106
http://www.raywenderlich.com/108522/whats-new-in-swift-2
What have I missed?
Part of the problem is that Swift 2 has continued to evolve past WWDC. So even this year's WWDC videos are already potentially out of date, or at least not the whole story.
Unfortunately, at this time there is no official "transition guide" from Apple as such.
The Swift Programming Language (Swift 2) is always updated by Apple whenever they release a new version of Swift and is therefore one of the best sources for up to date information about Swift 2 (or later). There is plenty of explanation and example code of the entire language, not just the changes, but this is definitely at least on of the best sources for the information you are looking for right now.

How to swap functions (e.g.for tests) in pure functional programming

I'm trying to understand what is an FP-alternative to good old dependency injection from OOP.
Say I have the following app (pseudocode)
app() is where application starts. It allows user to register and list user posts (whatever). These two functions are composed out of several other functions (register does it step by step, imperatively, while list posts really composes them (at least this is how I understand function composition).
app()
registerUser(u)
validate(u)
persist(u)
callSaveToDB(u)
notify(u)
sendsEmail
listPosts(u)
postsToView(loadUserPosts(findUser(u)))
Now I'd like to test this stuff (registerUser and listPosts) and would like to have stubbed functions so that I don't call db etc - you know, usual testing stuff.
I know it's possible to pass functions to functions e.g
registerUser(validateFn, persistFn, notifyFn, u)
and have it partially applied so it looks like registerUser(u) with other functions closed over and so on. But it all needs to be done on app boot level as it was in OOP (wiring dependencies and bootstraping an app). It looks like manually doing this will take ages and tons of boilerplate code. Is there something obvious I'm missing there? Is there any other way of doing that?
EDIT:
I see having IO there is not a good example. So what if I have function composed of several other functions and one of them is really heavy (in terms of computations) and I'd like to swap it?
Simply - I'm looking for FP way of doing DI stuff.
The way to answer this is to drop the phrase "dependency injection" and think about it more fundamentally. Write down interfaces as types for each component. Implement functions that have those types. Replace them as needed. There's no magic, and language features like type classes make it easy for the compiler to ensure you can substitute methods in an interface.
The previous Haskell-specific answer, shows how to use Haskell types for the API: https://stackoverflow.com/a/14329487/83805

Is there any performance reasons to change a function into a static function?

When developing actionscript/flex in IntelliJ IDEA, there's this IDEA inspection that suggests that so-and-so private function can be turned into a static function.
I've been ignoring it for a while now, but I'm curious as to whether, in actionscript, there's any performance benefit of declaring functions that can be static as static.
Coming from a Java background, it seems odd to me for IDEA to be suggesting that a function be made static just because it can... yet such an inspection does not exist in the Java editor.
For example, IDEA would suggest that I make the following static:
private function eventName(attributeName:String):String {
return attributeName + EVENT_NAME_SUFFIX;
}
No. There is actually quite an incentive to do the opposite.
This should not be so - naturally, one would think static functions would be faster - but ActionScript 3 does not behave this way. Whoever wrote IDEA did not do their research on this, but rather they went with their instincts and with what should be true.
Here's one source of information on this subject:
http://blog.controul.com/2009/04/how-slow-is-static-access-in-as3avm2-exactly/

Using #properties for all instance variables coding standards

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.

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