35

Consider this C++11 code snippet:

#include <iostream>
#include <set>
#include <stdexcept>
#include <initializer_list>


int main(int argc, char ** argv)
{
    enum Switch {
        Switch_1,
        Switch_2,
        Switch_3,
        Switch_XXXX,
    };

    int foo_1 = 1;
    int foo_2 = 2;
    int foo_3 = 3;
    int foo_4 = 4;
    int foo_5 = 5;
    int foo_6 = 6;
    int foo_7 = 7;

    auto get_foos = [=] (Switch ss) -> std::initializer_list<int> {
        switch (ss) {
            case Switch_1:
                return {foo_1, foo_2, foo_3};
            case Switch_2:
                return {foo_4, foo_5};
            case Switch_3:
                return {foo_6, foo_7};
            default:
                throw std::logic_error("invalid switch");
        }
    };

    std::set<int> foos = get_foos(Switch_1);
    for (auto && foo : foos) {
        std::cout << foo << " ";
    }
    std::cout << std::endl;
    return 0;
}

Whatever compiler I try, all seem to handle it incorrectly. This makes me think that I am doing something wrong rather than it's a common bug across multiple compilers.

clang 3.5 output:

-1078533848 -1078533752 134518134

gcc 4.8.2 output:

-1078845996 -1078845984 3

gcc 4.8.3 output (compiled on http://www.tutorialspoint.com):

1 2 267998238

gcc (unknown version) output (compiled on http://coliru.stacked-crooked.com)

-1785083736 0 6297428 

The problem seems to be caused by using std::initializer_list<int> as a return value of lambda. When changing lambda definition to [=] (Switch ss) -> std::set<int> {...} returned values are correct.

Please, help me solve this mystery.

1
  • As I point out in my answer below it is ironic that in the final proposal for initializer_list points out this exact scenario and dismisses it as an unlikely issue. Feb 4, 2015 at 19:58

3 Answers 3

32

From: http://en.cppreference.com/w/cpp/utility/initializer_list

The underlying array is not guaranteed to exist after the lifetime of the original initializer list object has ended. The storage for std::initializer_list is unspecified (i.e. it could be automatic, temporary, or static read-only memory, depending on the situation).

I don't think the initializer list is copy-constructable. std::set and other containers are. Basically it looks like your code behaves similar to "returning a reference to a temporary".

C++14 has something slightly different to say about the underlying storage - extending its lifetime - but that does not fix anything having to do with the lifetime of the initializer_list object, let alone copies thereof. Hence, the issue remains, even in C++14.

The underlying array is a temporary array, in which each element is copy-initialized (except that narrowing conversions are invalid) from the corresponding element of the original initializer list. The lifetime of the underlying array is the same as any other temporary object, except that initializing an initializer_list object from the array extends the lifetime of the array exactly like binding a reference to a temporary (with the same exceptions, such as for initializing a non-static class member). The underlying array may be allocated in read-only memory.

11
  • 4
    Yep, that's exactly what happens. The init list is backed by a stack-allocated array, and that array goes poof when the lambda returns. Feb 4, 2015 at 10:29
  • 4
    initializer_list is copyable (hence this compiles) but it only performs a shallow copy. Frankly I find this to be an awful C++11 "feature". Fortunately, yes, this is fixed in C++14, in which the lifetime of the underlying array is extended during a copy of the initializer_list, much like it would if you bound it to a reference. Unfortunately, GCC 4.9.2 in C++14 mode still gets it wrong. I haven't tested with HEAD. Feb 4, 2015 at 10:39
  • 1
    That is certainly very true. It is not a very useful feature ;-)
    – emvee
    Feb 4, 2015 at 10:40
  • 4
    "Fortunately, this 'oversight' could/should have been fixed in C++14", which sentence of the paragraph you pasted indicate this should be fixed and that this was an oversight?: "The lifetime of the underlying array is the same as any other temporary object, except that initializing an initializer_list object from the array extends the lifetime of the array exactly like binding a reference to a temporary". Creating a reference initialized by other reference-type variable doesn't extend the lifetime of the original temporary until the last reference exists. Array is a temporary Feb 4, 2015 at 11:06
  • 4
    @LightnessRacesinOrbit the array's lifetime is extended until the lifetime of the initializer_list object it is used to initialize ends; but that initializer_list object is the temporary return value of the lambda, whose lifetime ends at the ;. (That's not even counting the fact that the array in the question is "bound" in an return statement, so normally you don't get any lifetime extension at all.)
    – T.C.
    Feb 4, 2015 at 11:14
16

The problem is that you are referencing an object that no longer exists and therefore you are invoking undefined behavior. initializer_list seems underspecified in the C++11 draft standard, there are no normative sections that actually specify this behavior. Although there are plenty of notes that indicate this will not work and in general although notes are not normative if they don't conflict with the normative text they are strongly indicative.

If we go to section 18.9 Initializer lists it has a note which says:

Copying an initializer list does not copy the underlying elements.

and in section 8.5.4 we have the following examples:

typedef std::complex<double> cmplx;
std::vector<cmplx> v1 = { 1, 2, 3 };

void f() {
    std::vector<cmplx> v2{ 1, 2, 3 };
    std::initializer_list<int> i3 = { 1, 2, 3 };
}

with the following notes:

For v1 and v2, the initializer_list object and array created for { 1, 2, 3 } have full-expression lifetime. For i3, the initializer_list object and array have automatic lifetime.

These notes are consistent with the initializer_list proposal: N2215 which gives the following example:

std::vector<double> v = {1, 2, 3.14};

and says:

Now add vector(initializer_list<E>) to vector<E> as shown above. Now, the example works. The initializer list {1, 2, 3.14} is interpreted as a temporary constructed like this:

const double temp[] = {double(1), double(2), 3.14 } ;
initializer_list<double> tmp(temp,
sizeof(temp)/sizeof(double));
vector<double> v(tmp);

[...]

Note that an initializer_list is a small object (probably two words), so passing it by value makes sense. Passing by value also simplifies inlining of begin() and end() and constant expression evaluation of size().

An initializer_list s will be created by the compiler, but can be copied by users. Think of it as a pair of pointers.

The initializer_list in this case just holds pointers to an automatic variable which will not exist after exiting the scope.

Update

I just realized the proposal actually points out this misuse scenario:

One implication is that an initializer_list is “ pointer like” in that it behaves like a pointer in respect to the underlying array. For example:

int * f(int a)
{ 
   int* p = &a;
   return p; //bug waiting to happen
}

initializer_list<int> g(int a, int b, int c)
{
   initializer_list<int> v = { a, b, c };
   return v; // bug waiting to happen
} 

It actually takes a minor amount of ingenuity to misuse an initializer_list this way. In particular, variables of type initializer_list are going to be rare.

I find the last statement(emphasis mine) particularly ironic.

Update 2

So defect report 1290 fixes the normative wording and so it now covers this behavior, although the copy case could be more explicit. It says:

A question has arisen over expected behavior when an initializer_list is a non-static data member of a class. Initialization of an initializer_list is defined in terms of construction from an implicitly allocated array whose lifetime "is the same as that of the initializer_list object". That would mean that the array needs to live as long as the initializer_list does, which would on the face of it appear to require the array to be stored in something like a std::unique_ptr within the same class (if the member is initialized in this manner).

It would be surprising if that was the intent, but it would make initializer_list usable in this context.

The resolution fixes the wording and we can find the new wording in the N3485 version of the draft standard. So section 8.5.4 [dcl.init.list] now says:

The array has the same lifetime as any other temporary object (12.2), except that initializing an initializer_- list object from the array extends the lifetime of the array exactly like binding a reference to a temporary.

and 12.2 [class.temporary] says:

The lifetime of a temporary bound to the returned value in a function return statement (6.6.3) is not extended; the temporary is destroyed at the end of the full-expression in the return statement.

8
  • @dyp I saw you left a comment that you since removed. If you see a normative section that specifies the lifetime and copying like the notes do, please let me know. Feb 5, 2015 at 1:17
  • 1
    I think the binding of a temporary array to a reference does specify the lifetime (in [dcl.init.list]/6). This also agrees with the strange fact that you may not have constexpr auto x = {1,2}; locally, but constexpr static auto x = {1,2};: the lifetime of the temporary array in the first example is extended to the lifetime of an automatic object, and in the second to a static object. Being an object of static storage duration, it is legal to deal with addresses.
    – dyp
    Feb 5, 2015 at 1:28
  • 1
    But it's not very explicit, and the results are rather surprising IMHO. I'd guess that writing it explicitly like template<class T> using id = T; auto&& il = id<int[]>{1, 2}; might have been a better idea. That array is noncopyable, so you see the weird reference semantics when you try to pass it to or try to return it from a function.
    – dyp
    Feb 5, 2015 at 1:30
  • 1
    As far as I understand it, the lifetime is similar to this example, with the sole difference that the lifetime is also extended when you write initializer_list<int> x = initializer_list<int>{1,2,3}; (which is really more like the id<int[]> example above, but the reference is hidden inside intializer_list)
    – dyp
    Feb 5, 2015 at 1:36
  • 1
    @dyp yes paragraph does say the lifetime is the same as an array but that does not cover copying which the non-normative note in 18.9 covers. So I don't think that is enough to prove it won't work, or at least it is no specific enough for me. Considering the last line I highlight from the proposal this just seems like an oversight. The proposers felt this was obvious but clearly it is not. Feb 5, 2015 at 4:05
2

So, initializer_lists do not extend the lifetime of their referenced array when they are themselves copied or moved to the result of the copy/move. This makes returning them problematic. (they do extend the lifetime of the referenced array to their own lifetime, but this extension is not transitive over elision or copies of the list).

To fix this problem, store the data, and manage its lifetime manually:

template<size_t size, class T>
std::array<T, size> partial_array( T const* begin, T const* end ) {
  std::array<T, size> retval;
  size_t delta = (std::min)( size, end-begin );
  end = begin+delta;
  std::copy( begin, end, retval.begin() );
  return retval;
}
template<class T, size_t max_size>
struct capped_array {
  std::array<T, max_size> storage;
  size_t used = 0;
  template<size_t osize, class=std::enable_if_t< (size<=max_size) >>
  capped_array( std::array<T, osize> const& rhs ):
    capped_array( rhs.data(), rhs.data()+osize )
  {}
  template<size_t osize, class=std::enable_if_t< (size<=max_size) >>
  capped_array( capped_array<T, osize> const& rhs ):
    capped_array( rhs.data(), rhs.data()+rhs.used )
  {}
  capped_array(capped_array const& o)=default;
  capped_array(capped_array & o)=default;
  capped_array(capped_array && o)=default;
  capped_array(capped_array const&& o)=default;
  capped_array& operator=(capped_array const& o)=default;
  capped_array& operator=(capped_array & o)=default;
  capped_array& operator=(capped_array && o)=default;
  capped_array& operator=(capped_array const&& o)=default;

  // finish-start MUST be less than max_size, or we will truncate
  capped_array( T const* start, T const* finish ):
    storage( partial_array(start, finish) ),
    used((std::min)(finish-start, size))
  {}
  T* begin() { return storage.data(); }
  T* end() { return storage.data()+used; }
  T const* begin() const { return storage.data(); }
  T const* end() const { return storage.data()+used; }
  size_t size() const { return used; }
  bool empty() const { return !used; }
  T& front() { return *begin(); }
  T const& front() const { return *begin(); }
  T& back() { return *std::prev(end()); }
  T const& back() const { return *std::prev(end()); }

  capped_array( std::initializer_list<T> il ):
    capped_array(il.begin(), il.end() )
  {}
};

the goal here is simple. Create a stack based data type that stores a bunch of Ts, up to a cap, and can handle having fewer.

Now we replace your std::initializer_list with:

auto get_foos = [=] (Switch ss) -> capped_array<int,3> {
    switch (ss) {
        case Switch_1:
            return {foo_1, foo_2, foo_3};
        case Switch_2:
            return {foo_4, foo_5};
        case Switch_3:
            return {foo_6, foo_7};
        default:
            throw std::logic_error("invalid switch");
    }
};

and your code works. The free store is not used (no heap allocation).

A more advanced version would use an array of uninitialized data and manually construct each T.

7
  • You see, this very thing can be done using std::vector/std::set/std::list instead of capped_array. The useful property of std::initializer_list is that is can be used to initialize each of them (std::vector/std::set/std::list) alike. Just std::<something> foo = get_foos(Switch_1);. This is just a matter of convenience, the prettiness I wanted to have in my code.
    – GreenScape
    Feb 5, 2015 at 7:49
  • 1
    @GreenScape I thought you where trying to avoid the free store (a needless memory allocation on the heap). Creating a type that can be used to construct nearly arbitrary containers is easy -- just overload template<class C>operator C() with an extra SFINAE test that it can be constructed via (iterator, iterator). This is why posting motivation in your question (if only as an aside) is useful. Feb 5, 2015 at 14:03
  • you see, template<class C>operator C() only enables easy copy initialization. For instance, if I have a std::set<int> a = ...; and later I want to insert more values to this container, with a std::initializer_list this can be done in very clean manner: a.insert(get_foos(Switch_1)). But if return value of a get_foos() is not an initializer list things get pretty messy. You have to call get_foos() before insert and store the result in some kind of aux variable, that is not very readable when you have to call get_foos() many times in a row.
    – GreenScape
    Feb 5, 2015 at 14:26
  • @GreenScape Then implement C +concat= X or concat( C, X ) with proper overloads. On the left we detect if we are a sequence or associative container (sequence get insert( end(c), s, f ), associative get insert( s, f ) if you really want this. Or define different operations for associative containers and sequence containers (easier, as less mess around with insert overload and detection, which gets really messy). Admittedly at this point it gets harder than the simple one above. But initializer_list just doesn't work, so... Feb 5, 2015 at 14:37
  • yeah, I just wanted a simple solution, it seemed possible but alas, not very likely for C++ as it is, it yields UB :( So what's left is to use not so convenient but simple solution. In my case it's std::set. Thanks!
    – GreenScape
    Feb 5, 2015 at 16:02

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

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