Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have been playing with auto and I noticed that for most cases you can replace a variable definition with auto and then assign the type.

In the following code section w and x are equivalent (default initialized int, but lets not get into potential copies). Is there a way to declare z such that it has the same type as y?

int w{};
auto x = int{};
int y[5];
auto z = int[5];
share|improve this question
3  
The potential copies are important. You can't do this because you can't copy arrays. –  David Brown Jun 5 '13 at 20:17
1  
Not "default initialized int", but "zero-initialized int" –  Andy Prowl Jun 5 '13 at 20:20
    
Apparently, there is a problem creating a temporary array, and then copying it, as @DavidBrown intimated. Even using a typedef for an array type fails, because of this. –  jxh Jun 5 '13 at 20:44
    
Implicit default constructor for an int does zero-initialize, unlike an unitialized int when has whatever garbage was already at the location. –  Graznarak Jun 5 '13 at 20:46
    
@Graznarak: Except it isn't an "implicit default constructor". Zero-filling of int (for example) occurs for value initialization and static initialization, but not default initialization. –  Ben Voigt Jun 6 '13 at 15:30

3 Answers 3

up vote 18 down vote accepted

TL;DR

template<typename T, int N> using raw_array = T[N];

auto &&z = raw_array<int,5>{};

Your example of auto z = int[5]; isn't legal any more than auto z = int; is, simply because a type is not a valid initializer. You can write: auto z = int{}; because int{} is a valid initializer.

Once one realizes this, the next attempt would be:

auto z = int[5]{};

Note that your int y[5] does not have any initializer. If it had then you would have jumped straight here.

Unfortunately this does not work either for obscure syntax reasons. Instead you must find a legal way to name the array type in an initializer. For example, a typedef name can be used in an initializer. A handy reusable template type alias eliminates the burdensome requirement of a new typedef for every array type:

template<typename T, int N> using raw_array = T[N];

auto z = raw_array<int,5>{};

Aside: You can use template type aliases to fix the weird 'inside-out' syntax of C++, allowing you to name any compound type in an orderly, left-to-right fashion, by using this proposal.


Unfortunately due to the design bug in C and C++ which causes array-to-pointer conversions at the drop of a hat, the deduced type of the variable z is int* rather int[5]. The resulting variable becomes a dangling pointer when the temporary array is destroyed.

C++14 introduces decltype(auto) which uses different type deduction rules, correctly deducing an array type:

decltype(auto) z = raw_array<int,5>{};

But now we run into another design bug with arrays; they do not behave as proper objects. You can't assign, copy construct, do pass by value, etc., with arrays. The above code is like saying:

int g[5] = {};
int h[5] = g;

By all rights this should work, but unfortunately built-in arrays behave bizarrely in C and C++. In our case, the specific problem is that arrays are not allowed to have just any kind of initializer; they are strictly limited to using initializer lists. An array temporary, initialized by an initializer list, is not itself an initializer list.


Answer 1:

At this point Johannes Schaub makes the excellent suggestion that we can use temporary lifetime extension.

auto &&z = raw_array<int,5>{};

decltype(auto) isn't needed because the addition of && changes the deduced type, so Johannes Schaub's suggestion works in C++11. This also avoids the limitation on array initializers because we're initializing a reference instead of an array.

If you want the array to deduce its length from an initializer, you can use an incomplete array type:

template<typename T> using unsized_raw_array = T[];

auto &&z = unsized_raw_array<int>{1, 2, 3};

Although the above does what you want you may prefer to avoid raw arrays entirely, due to the fact that raw arrays do not behave like proper C++ objects, and the obscurity of their behavior and the techniques used above.

Answer 2:

The std::array template in C++11 does act like a proper object, including assignment, being passable by value, etc., and just generally behaving sanely and consistently where built-in arrays do not.

auto z = std::array<int,5>{};

However, with this you miss out on being able to have the array type infer its own length from an initializer. Instead You can write a make_array template function that does the inference. Here's a really simple version I haven't tested and which doesn't do things you might want, such as verify that all the arguments are the same type, or let you explicitly specify the type.

template<typename... T>
std::array<typename std::common_type<T...>::type, sizeof...(T)>
make_array(T &&...t) {
    return {std::forward<T>(t)...};
}

auto z = make_array(1,2,3,4,5);
share|improve this answer
    
But I thought he wanted it to be uninitialized like y, or default initialized like int{}. Are you saying int[5]{} would work? –  jxh Jun 5 '13 at 22:23
    
@jxh Yes, you can have a default initializer: auto z = raw_array<int,100>{}; –  bames53 Jun 5 '13 at 22:27
    
I can't get your first success case to work: ideone.com/Hn7X6q –  jxh Jun 5 '13 at 22:28
    
raw_array example has same problem: ideone.com/z0wN2l –  jxh Jun 5 '13 at 22:33
2  
What you can do is using lifetime extension with references, i.e auto&&. –  Johannes Schaub - litb Jun 5 '13 at 22:41

Not quite the same, but you could use array:

auto z = std::array<int, 5>();
share|improve this answer
4  
For giggles, we made a make_array function some time ago. –  Kerrek SB Jun 5 '13 at 20:48

decltype works with g++ 4.9.0 20130601 for this:

#include <iostream>
#include <algorithm>

static std::ostream& logger = std::clog;

class A {
    static int _counter;
    int _id;
  public:
    A() : _id(++_counter) {
        logger << "\tA #" << _id << " c'tored\n";
    } 

    ~A() {
        //logger << "\tA #" << _id << " d'tor\n";
    } 

    inline int id() const{
        return _id;
    }
};
int A::_counter(0); 

std::ostream& operator<<(std::ostream& os, const A& a) {
    return os << a.id();
}

int main() {

    auto dump = [](const A& a){ logger << a << " ";};

    logger << "x init\n";
    A x[5]; 
    logger << "x contains: "; std::for_each(x, x+5, dump);

    logger << "\ndecltype(x) y init\n";
    decltype(x) y;
    logger << "y contains: ";  std::for_each(y, y+5, dump);
    logger << std::endl;

    return 0;
}

Output:

x init
    A #1 c'tored
    A #2 c'tored
    A #3 c'tored
    A #4 c'tored
    A #5 c'tored
x contains: 1 2 3 4 5 
decltype(x) y init
    A #6 c'tored
    A #7 c'tored
    A #8 c'tored
    A #9 c'tored
    A #10 c'tored
y contains: 6 7 8 9 10 
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.