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I need to dynamically allocate a two dimensional array of smart pointers but the syntax for it is confusing me. I need this to be dynamic:

std::unique_ptr<someClass> myArray[size1][size2];

So from what I understand I create a pointer to a pointer to the type:

someClass** myArray; //actaully the type is std::unique_ptr<someClass> but I'll just keep it simple

Then to allocate it I do:

myArray* = new someClass*[size1];
for(int i = 0; i < size1; i++)
    myArray[i] = new someClass[size2];

But this doesn't use smart pointers which means I will have to manually delete it later, and I don't know how to make these pointers smart pointers;

The type is std::unique_ptr but then I need a pointer to a pointer to the type, so I tried:

std::unique_ptr<std::unique_ptr<std::unique_ptr<someClass>>> myArray;

But after this I'm lost on how I would allocate it. Could someone please help me out?

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A 1D vector<unique_ptr<T>> should be a good replacement for a 2D array of smart pointers. –  juanchopanza Mar 18 '13 at 22:53
Also, two-dimensional arrays aren't double pointers. –  user529758 Mar 18 '13 at 22:54
In C++, "two-dimensional array of X" is spelled std::vector<std::vector<X> >. –  n.m. Mar 18 '13 at 23:11
@n.m. The caveat is that in that case the memory is not contiguous. That may or may not be an issue, but I usually say "the 2D array of X is an std::vector<X> and some (not so) clever indexing". –  juanchopanza Mar 18 '13 at 23:14

1 Answer 1

I'll show you how to solve your problem specifically and how to approach problems like this one in general.

In general, just like any problem that gets too complex, try to break it down. The tool for breaking down complex type declarations in C and C++ has long been the "typedef". Here is how you approach it for cascaded type definitions like the one you are having: take the innermost wrapping type, i.e. the unique_ptr wrapping your class, and make a typedef for the type you want to wrap. Then, proceed doing the same for the type which that type is wrapping, until you are at the outermost type.

This is tangentially related to your question only, but I want to mention it, because you might run into a similar issue like the one you are having now with templates later. Since C++11 you can more conveniently also define aliases for types involving template parameters with the "using" clause: http://en.cppreference.com/w/cpp/language/type_alias. Go check out that link if that is of interest to you in this context or becomes relevant in the future!

To your specific problem. The function "test_dynamic_2darray1" builds a two-dimensional 10x10 array of smart pointers. When you run this code, you should see 100 lines of the output from the destructor, just when the managed array goes out of scope.

size_t destructor_count = 0;
class MyClass {
    ~MyClass() {
        std::cout << "Destructor call #" << ++destructor_count << std::endl;

typedef std::unique_ptr<MyClass[]> ManagedC;

void test_dynamic_2darray1() {
    size_t dimension1 = 10, dimension2 = 10;

    auto managed_array = std::unique_ptr<ManagedC[]>(new ManagedC[dimension1]);
    for (size_t i = 0; i < dimension1; ++i)
        managed_array[i] = ManagedC(new MyClass[dimension2]);

Compare that to this code, where the destructors of the dynamically allocated class instances will not be called and you see no output:

void test_dynamic_2darray2() {
    size_t dimension1 = 10, dimension2 = 10;

    auto simple_array = new MyClass*[dimension1];
    for (size_t i = 0; i < dimension1; ++i)
        simple_array[i] = new MyClass[dimension2];

I hope I have been able to answer your question! :) Let me know if you want me to elaborate on something! I also wrote a related blog post the other day that may interest you: http://frankriesecodingblog.blogspot.com/2015/01/performance-of-dynamic-multi.html. I am posting it here, because it shows different approaches to multi-dimensional dynamic arrays and looks into the performance of the often suggested method of using vectors of vectors.

Last but not least, let me mention your use of int to iterate over arrays. I hope this isn't turning into a pet peeve of mine, but I see this being done a lot. You should probably use size_t. Why? For example, on my 64 bit machine "int" is 32 bit, but addresses, represented by size_t, are 64 bit. This misuse of int has been the cause of many bugs, in particular for porting 32 bit applications to 64 bit machines. If you need a signed type, for uses such as offsets between array addresses, a better use would probably be ptrdiff_t.

share|improve this answer
I tried to apply your solution to my problem but I am getting the following error when I try to pass my 2D array of doubles to a function for processing: error C2664: 'functionName' : cannot convert parameter 7 from 'std::unique_ptr<_Ty> *' to 'double **'. Basically I would like to create the 2D double array and allocate the memory, there is some initialisation code and then it gets passed to a function. In case the function throws an exception I want to use smart pointers to help clear up afterwards. –  Ben Feb 20 at 14:26
I guess that what I need to do is setup dimension2 (in your example) as dumb pointers, but initialise them using smart pointers and assigning them to the 2D array using the .get()? –  Ben Feb 20 at 14:31

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