One problem with matchstar is that it isn't greedy enough. Proper regex * matches a maximal substring; this one quits as soon as the remainder or the regex after the * is satsified.
As a result, its computational complexity is too high. This program slows exponentially with the number of stars in the expression, I think.
I think, most important is to be aware that your question is about an exercise that (apparently) at one time was designed to be easy and interesting.
However, that was long ago, and meanwhile both hardware and software has progressed. It is no longer easy to access physical memory. And, at least...
In particular, I don't know if it works in Linux.
As I recall the OP stated that he's working in Linux.
I could Google the formula faster than I could write it on the examination paper
and it's insanely demotivating
and thoroughly pointless, a gigantic waste of effort by all parties concerned
the university has to waste lecturer time marking that question, you know
and the students who don't memorize stuff by rote will get marked down, even though they're perfectly capable of creating stuff using a rotation matrix
Well, I don't have much experience in CS, so my opinion might not be worth much. But I recall exam questions in the compiler class which appeared to be high-level design or theory, requiring creative thought, but were actually regurgitation.
So if you attempted to solve it yourself, even getting a valid answer, it would be wrong because it wasn't what was written on the blackboard four weeks ago.
In the digital circuit course I TA'ed, I'd try to put design questions on the exams. But that worked better because the design space is smaller. There would only be a couple ways to design the circuit, one of which would be regurgitation.
Usually most students regurgitated, half the remainder who made educated guesses were correct, and the rest drew something and then maybe scribbled it out, getting partial credit.
But when it comes to programs, there are too many solutions. It's impossible to grade them sanely. Unfair even to have to write the answer with pencil in the first place.
You can't prove that two functions identical except for variable names and whitespace are the product of copying. The best solution is the most likely to occur (one would hope).
So I don't see what's wrong with your school now, at my school they were either too lazy to look at the assignments or they just ignored it if they saw people copied stuff, that sucks!
Here's something we all learned on Day 1 of C++, which we take for granted but doesn't clearly follow from the wording of the Standard.
Given a class S, we can define its constructor
struct S { S(); };
S::S() { … }
But the Standard seems to allow this just as well:
struct S { S(); };
S() { …...
@Potatoswatter 12.1/1 is only for in-class constructor declarations
the text there could be clearer, but that's the intention
(in an out-of-class constructor definition the S::S does not refer to the class. it's not a class name, but it is a function name and refers to the constructor)
Tail recursion doesn't use the stack, so you can eliminate it more trivially. In general, converting recursion to iteration requires introducing an explicit stack structure.
Which is easy in C++ with std::stack, but more painful in C.
But, a namespace scope constructor definition still differs from other function definitions in that it omits the return type. (Same with conversion operators and destructors.)
12.4 which is about destructors has that reminder: "... is used to declare the destructor in a class definition.". sadly 12.1 for constructors doesn't. but it's clear it should have. because by the rules in 3.4.3.1, a S::S in that out of class definition doesn't refer to the class
Also I'm confused by the contradiction: 12.1 begins by saying "the constructor does not have a name" (which was the idea I'm familiar with) yet 3.4.3.1 describes how to name the constructor.
@Potatoswatter 7p9 allows one to omit the return type (decl-specifier-seq) for constructor declarations)
and the rule in 3.4.3.1 makes so that S::S refers to the constructor. so an out-of-class constructor definition it doesn't need a special constructor declaration syntax
that it is a constructor definition follows from the fact that the name in the declaration refers to the constructor.
@Nils Yeah, that's a little wart. If the next regex character is a star, treat the current regex character as a wildcard. Then upon handling the star, go back one character and redo.
I looked at an early draft of the standard, circa 1993, to try to figure it out. Back then, the constructor was explicitly a member function with a name coinciding with the class. It could be called normally.
it would cause a problem because function names normally hide class names. so the constructor would always hide the injected class name.
struct A { int A; }; // allowed
now when you say A::A, it will not refer to the constructor, and not refer to the class, but refer to the data member.
I think there is no way to refer to the implicitly declared default constructor for such a class :) you can refer to the injected class name by saying struct A::A
… maybe not. The word "inject" does not occur, and since there's no table of contents and so many things changed over the next 5 years, it's hard find positive evidence.
@JohannesSchaublitb Likewise, in the scope of a member function, attempting a function style conversion (constructing a temporary) would actually call the constructor on this.
@Nils it took me a little while to verify that it works properly. Note that "*", but not ".", will match the terminating '\0'
@JohannesSchaublitb I guess they prioritized features and things that actually make a difference for C++11. At least if it's on their radar, maybe C++13 can include a "bugfix"
@Potatoswatter the problem is that you are only allowed to use such a constructor "name" in an out of class constructor definition or in an in-class using declaration.
I'm personally fighting GCC on another front: I've got a functor with a pointer to member but I don't know how to overload operator()(C&& c, Args... a) such that the functor accepts both objects and (possibly smart) pointers.
Using decltype won't trigger SFINAE; any idea to trick GCC?
I think the cut is to be done at primary-expression.nowhere does the spec seem to say that a type name is a primary-expression. :) but now It's too late to return back at that discussion to the committee.:) but I think it makes sense
@FredOverflow Using or not using copy and swap is orthogonal to making the strong exception guarantee. If you have a strong swap, you can write a strong move assignment.
Not so sure about weaker guarantees.
Ditto regarding the nothrow guarantee. The strong guarantee can also be implemented in a move assignment.
Look at it that way: move assignment is half the work of swap.
You can implement either of those and then implement the other one in terms of the first.
posted a new comment on cpp-next.com: "“Except for enums, every value with a name is an lvalue.”. I know I’m going to annoy you by this, but I want to inform the innocent reader that integer, pointer and member pointer template parameters aren’t lvalues either."
with these most recent insights I should have added "type parameters" to the list. aaahaha
i flagged my question saying "It's too confusing to me whether this question belongs on Stackoverflow.SE or Programmers.SE. Stackoverflow has way more licensing+lgpl questions than Programmers. And according to the FAQ my question is ontopic. Requesting a good decision on this. Thanks."
The space complexity doesn't make sense because O(N) is required for the array in the first place. If an in-place algorithm is desired, that's not a big-O matter.
Sorting can be done in-place in O(N log N) time, so why is it not an option?