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I would like to add a function that returns the .size() value as an integer, instead of unsigned integer.

Edit: Due to comments, i explain more detailed:

I have code:

int something = 3;
if(arr.size() > something) 

Which will produce compiler warning, and i dislike adding (int) to every place where i have this. So, a solution i thought it would be nice to have sizei() function:

int something = 3;
if(arr.sizei() > something) 

Which wouldnt produce a warning.

So, im not wanting to create a separate function, but a function in the std::vector itself.

Edit: Seems like the only way to do this is to create another function, such as:

template <typename T>
inline int sizei(const T &arr){
    return (int)arr.size();
}

On the positive side: this doesnt seem to increase my executable size at all.

share|improve this question
    
Why? What's your use-case to have count of -1? –  littleadv Jun 15 '11 at 17:13
    
I'm not sure this question makes any sense. Do you have a specific problem with the type being returned? –  Adrian Conlon Jun 15 '11 at 17:13
1  
The question was unreasonably downvoted. Some compilers emit warnings on mixed signed-unsigned comparisons, and the only good use case I've found for unsigned numbers is well-defined modular arithmetic. Using unsigned to restrict the domain is (almost) always the wrong thing to do, IMO. –  zvrba Jun 15 '11 at 17:17
2  
Of course you shouldn't compare mixed signs, but if this comes up you should convert the result of size() at the place where you need it, i.e. the conversion. That way you localize the problem and don't need to change the semantics of the vector, and the inherently unsigned nature of a "size". –  Kerrek SB Jun 15 '11 at 17:20
3  
Oh, and if you want to irritate the people telling you off, remind them that they shouldn't be using size_t, rather std::vector<whatever>::size_type ;-) –  Steve Jessop Jun 15 '11 at 17:52

6 Answers 6

up vote 2 down vote accepted

As a rule, in C and C++ you should never use an unsigned type such as size_t to restrict the domain. That's because (1) these languages provide no range checking, and (2) they do provide unreasonable implicit promotions. No range checking means (1) no advantage, and unreasonable implicit promotions means (2) very undesirable disadvantages, so it's plain stupid thing to do: no advantage, very undesirable disadvantages.

However, the standard libraries for these languages do that. They do it for historical reasons only, caught irreversibly in early decisions which at one time made sense. This has both extremely silly consequences such as C99 requiring 17 (!) bits for ptrdiff_t, and it has the aforementioned extremely undesirable consequences such as using inordinately much time on hunting down bugs resulting from implicit promotions (etc.). For example, in C++ you are practically guaranteed that std::string( "bah!" ).length() < -5 – which can easily trip you up and anyway is as silly as it is possible to design.

Now, you can't infuse new member functions in std::vector, but you can add a freestanding function. A good name is countOf. Template it so that it can be applied to just about anything (raw arrays, vectors, etc.).

The triad of functions startOf, endOf and countOf were, as far as I know, first identified by Dietmar Kuehl. C++0x will have std::begin and std::end, but AFAIK no corresponding std::size. In the meantime you can just define this support, which allows you to treat any kinds of container plus raw arrays the same.

An example implementation & further discussion is provided at my blog.


EDIT Adding some code, because it's requested in the comments.

Detection of suitable iterator type:

template< typename Type >
struct It
{
    typedef typename Type::iterator T;
};

template< typename Type >
struct It< Type const >
{
    typedef typename Type::const_iterator T;
};

template< typename ElemType, Size N >
struct It< ElemType[N] >
{
    typedef ElemType* T;
};

And the countOf, startOf and endOf functions, using that deduced iterator type:

template< typename T >
inline Size countOf( T const& c )           { return static_cast<Size>( c.size() ); }

template< typename T, Size N >
inline Size countOf( T (&)[N] )             { return N; }

template< typename T >
inline typename It<T>::T startOf( T& c )    { return c.begin(); }

template< typename T, Size N >
inline T* startOf( T (&a)[N] )              { return a; }

template< typename T >
inline typename It<T>::T endOf( T& c )      { return c.end(); }

template< typename T, Size N >
inline T* endOf( T (&a)[N] )                { return a + N; }

where Size is a typedef for ptrdiff_t.

Note: in 64-bit Windows int (and even long) is 32-bit. Hence, int is in general not sufficient for a really large array. ptrdiff_t is guaranteed to be able to represent the difference between any two pointers, when that difference is well-defined.


Cheers & hth.

share|improve this answer
    
"early decisions which at one time made sense" - did they ever make sense? If there were no comparison operators (and possibly you'd need there to be no mixed arithmetic either, just explicit conversion) between signed and unsigned types, then I could sort of see the point of using unsigned types in the standard libraries. As things stand, though, you can't use only signed types, you can't use only unsigned types, and you can't safely mix them. Which as you say is a bit of a bind. –  Steve Jessop Jun 15 '11 at 18:21
    
I think it's important that your types respect the fundamental properties of what they represent. It makes perfect sense, for example, to talk about the difference between two sizes, and the standard formula for that difference is abs(size1, size2). If this doesn't work for the type you're using for sizes, then you're using the wrong type. –  James Kanze Jun 15 '11 at 18:22
    
@James: but conversely, if the type you're using for indexes doesn't let you talk about a signed difference, then you're using the wrong type. So you can't use the same fixed-width type for both sizes and indexes, and you can't use a pair of corresponding signed/unsigned types because they don't fit, you can't have the signed one express signed differences in range of the unsigned one and the unsigned one express absolute differences in range of the signed one. Introduce a bigint builtin type to C and C++ and we could have sensible arithmetic, but we'd lose that close-to-the-metal vibe. –  Steve Jessop Jun 15 '11 at 18:29
    
@Steve: the only concrete example I know of where the unsigned size type makes sense, is 16-bit x86 programming. Then the other options would be either 32-bit signed type, with some inefficiency incurred, or 16-bit signed type with string size limited to 32KB (where conceivably one might need e.g. a 48KB string!). This conundrum is reflected by the 17-bit C99 requirement for ptrdiff_t, which is signed and needs to be able to represent the difference between any two sizes. In earlier discussions about this, on Usenet, I've taken the stand that one could have different rules for e.g. embedded. –  Cheers and hth. - Alf Jun 15 '11 at 18:32
    
@Alf: what about if ptrdiff_t didn't have to represent the difference between any two values of type size_t, just the difference between any two sizes of actual objects? Then you'd use a signed type for everything. Both kinds of difference work for real objects and pointers, they just don't work for the types (and hence James still doesn't get his, "types respect the fundamental properties of what they represent"). distance(INT_MAX, INT_MIN) is either undefined or defined to be an absurd value (wraparound), but happily doesn't represent a real distance. –  Steve Jessop Jun 15 '11 at 18:41

First of all, why would you want that? I don't see any reason, or advantage:

Anyway, you can do this:

template<typename T>
int size(const std::vector<T> &v) { return (int) v.size(); }

//use
std::vector<int> ints;
//...
int count = size(ints);

Still I don't see any point in doing that. You can simply write:

int count = (int) ints.size(); 

But I would still say its not better than the following :

size_t count = ints.size(); //don't prefer anything over this. Always use size_t

Advice: avoid using int for size. Prefer size_t.


As for the edit in your question. Why don't you use size_t as:

size_t something = 3;
if(arr.size() > something) 

No warning. In my opinion, if you choose the data type consistently throughout your program, you wouldn't come across a situation when you've to compare int with size_t which is defined as unsigned integral type.

Or if there is some legacy code which you've to work with, and which use int for size, then I think its better to use explicit cast when you need it, instead of adding a function in the framework itself, which hides the potential problem:

int something = /*some legacy code API call or something */;
if(arr.size() > (size_t) something) 

//or even better;
size_t something = (size_t) /*some legacy code API call or something */;
if(arr.size() > something) 
share|improve this answer
2  
@littleadv I think it is exactly what he asked for: "a function that returns the .size() value as an integer" –  Judge Maygarden Jun 15 '11 at 17:18
2  
why would you want to do this? It's not an uncommon requirement: Ex: You may have a function that returns the size of a particular named 'object' in some kind of structured storage. If the object is missing, -1 is returned, because we need to distinguish between missing and empty data. Also, missing data in these files is not sufficiently 'exceptional' to justify throwing). So, you often end up with code like if (object.dataSize("Foo") == sizeof(MyStruct)) { readIt(); }, which causes compiler warnings about comparing signed vs unsigned. –  Roddy Jun 15 '11 at 17:25
1  
@Nawaz: OK, removed downvote. But I'm not voting up, because this idea of using unsigned types for numbers, is IMHO social group thinking at its very worst. It's like a religious belief. Every single person knows that it's insane, but also (incorrectly) thinks that most everybody else think it's how things are. And expresses outwardly the belief that he/she thinks the group has. But, there are no advantages, not even the mnemonic one often cited (like comments, but typedef covers that). And there are lots of extreme disadvantages. Umpteen zillions of wasted (wo)man-hours. –  Cheers and hth. - Alf Jun 15 '11 at 18:12
1  
I'm tempted to give a -1 for the bad advice about using unsigned. unsigned, in C++, doesn't work very well, and causes any number of problems. It's best to avoid it unless your doing bitwise operations or need it's modulo properties. (I don't know where this mania for using unsigned types comes from. I've not seen it in any of the better tutorial works.) –  James Kanze Jun 15 '11 at 18:19
2  
+1 for using size_t as a vector can't have a negative size (at least not in this universe) –  Thomas Matthews Jun 15 '11 at 18:35

You can derive from vector as follows:

template<typename T>
class my_vector : public vector<T>
{
  // missing constructors!

  int size() const
  {
    if (vector<T>::size() > INT_MAX)
      throw std::range_error("too many elements in vector");
    return (int) vector<T>::size();
  }
};

The down-side is that you'll have to define and forward constructors yourself.

share|improve this answer
    
Missing constructors, missing virtual destructors... recipe for disaster. –  rubenvb Jun 15 '11 at 17:23
    
I wrote that constructors were missing. As for virtual destructors, they will be inherited from std::vector, if there are any at all. –  zvrba Jun 15 '11 at 17:24
    
@zvrba: there is no virtual destructor, and that is exactly the problem. If you delete your my_vector class from a pointer to base, you're screwed. And no, telling yourself not to do that is not going to prevent it from happening. –  rubenvb Jun 15 '11 at 17:29
2  
@rubenvb: "telling yourself not to do that is not going to prevent it from happening" I'm not sure why you'd dynamically allocate this class at all, but if you do then using shared_ptr<vector<something> >(new my_vector<something>(...)) would prevent anything bad from happening, since shared_ptr doesn't need a virtual destructor in order to get it right. And if not with shared_ptr, how are you managing these dynamically-allocated vectors? –  Steve Jessop Jun 15 '11 at 17:41
5  
@rubenvb: yeah, the claim "you cannot handle them polymorphically" is a bit misleading. There's one thing that you can't do with them, and that's polymorphically delete. But for containers, and for a derived class like like this that only adds a non-virtual function, it seems pretty unlikely to me that you'd use polymorphism at all, still less polymorphically delete. And shared_ptr can fake it for you. The real reason IMO not to do this is that it's futile to want everything to be a member function, when it could perfectly well be a non-member, but it's what the questioner asked for. –  Steve Jessop Jun 15 '11 at 18:03

I would favor using an explicit cast to int instead of a function: static_cast<int> (v.size()). Even better would be to always use size_t when dealing with memory sizes. For example, favor for (size_t i=0; i < v.size(); ++i) over for (int i=0; i < (int) v.size(); ++i). Use the right type for the job. You should not be comparing std::vector sizes with a signed type.

See the following references for why you should prefer size_t to int:

share|improve this answer
    
Please take the vector by const reference in vector_size –  Alexandre C. Jun 15 '11 at 17:30
    
it still remains unclear to me why exactly i shouldnt compare signed types to std::vector sizes... i've got through this signed/unsigned problems many times and i have learnt to just use ints for everything, in some rare cases i use unsigned ints when its REALLY needed. –  Rookie Jun 15 '11 at 17:37
    
@Rookie: the reason not to do that comparison is that in the event your signed value is negative, it will (probably) get converted to a very large unsigned value, and the comparison will come out claiming that the vector is smaller when it's really bigger. If you know that your integer value truly will never be negative, you might as well use an unsigned type for it, since it makes it easier to use the standard libraries. C++ containers simply don't play nicely with your preference for signed types: the compiler warning is telling you to bridge the gap by explicitly converting. –  Steve Jessop Jun 15 '11 at 17:57

Quick answer for .size() is: no. For vectors, the possibilities are its storage value and the alloc method (default new/delete, not normally overridden) along with methods that utilize InputIterator.

Most are going to ask why would you want a different size_t. If it's just the annoy warnings, you can cast or use unsigned integers to iterate/check against size(). (If it's a lot of code, you going to have to find/replace)... If it is handling empty conditions, you could wrap the vector in a class with some smarts. As an aside, since I don't know your problem at hand, a good place to look for ideas and already implemented features is std library's algorithms such as sort, for_each, find, and lots more.

For std algorithms, see: http://www.sgi.com/tech/stl/table_of_contents.html

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I'm a slow typer :) ... but I did guess everybody would say WHY? I say go with Nawaz's answer –  ginbot Jun 15 '11 at 17:42

While @Nawaz, in my opinion, provided the most appropriate answer, if you really want to add an additional member to std::vector<> it isn't really possible. @zvrba provided the only way that could be accomplished, but as stated in the comments there the std container types do not have virtual destructors and therefore are not meant to be subclassed from.

However, you could implement a new type of vector using a container adaptor, like this:

template <class T>
class my_vector
{
public:
   int size_i() const
   {
      return static_cast<int>(container_.size());
   }

private:
   std::vector<T> container_;
};

The drawback here is that you have to explicitly expose the functions of the container that you actually need to support. If you are using 'std::vector' normally throughout your code, this would likely be a significant change. See 'std::queue' for an implementation example of a container adaptor.

share|improve this answer
    
You could expose the contained vector by reference through a method. For example, std::vector& operator()() { return container_; } and then use it like so: arr().push_back(foo);. –  Judge Maygarden Jun 15 '11 at 18:40
    
Good point @Judge Maygarden, to take that a step further, you could potentially implement an implicit conversion operator to std::vector<T> and continue to use my_vec in the code (mostly) unmodified. –  Chad Jun 15 '11 at 19:05

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