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So I've recently become familiar with (and fell in love with) boost and c++11 smart pointers. It makes memory management SO much easier. And, on top of all that, they can usually still work with legacy code (through the use of the get call)

However, the big hole I keep running into is multidimensional jagged arrays. The correct way to do it is to have a boost::scoped_array<boost::scoped_array<double>> or vector<vector<double>>, which will clean up nicely. However, you cannot get a double** out of this easily to send to legacy code.

Is there any way to do this, or am I stuck with non-smart jagged arrays?

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What exactly is the API of your "legacy code"? I don't see how you could possibly pass a jagged array as double** - where's the size information? –  Casey Jul 12 '13 at 19:40

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I'd start with std::vector<std::vector<double>> for storage, unless the structure was highly static.

To produce my array-of-arrays, I'd produce a std::vector<double*> via transformation of my above storage, using syntax like transform_to_vector( storage, []( std::vector<double>& v ) { return v.data(); } ) (transform_to_vector left as an exercise to the reader).

Keeping the two in sync would be a simple matter of wrapping it in a small class.

If the jagged array is relatively fixed in size, I'd take a std::vector<std::size_t> to create my buffer (or maybe a std::initializer_list<std::size_t> -- actually, a template<typename Container>, and I'd just for( : ) over it twice, and let the caller pick what container it provided me), then create a single std::vector<double> with the sum of the sizes, then build a std::vector<double*> at the dictated offsets.

Resizing this gets expensive, which is a disadvantage.

A nice property of using std::vector is that newer APIs have full access to the pretty begin and end values. If you have a single large buffer, you can expose a range view of the sub arrays to new code (a structure containing a double* begin() and double* end(), and while we are at it a double& operator[] and std::size_t size() const { return end()-begin(); }), so they can bask in the glory of full on C++ container-style views while keeping C compatibility for legacy interfaces.

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If you're working in C++11, you should probably work with unique_ptr<T[]> rather than scoped_array<T>. It can do everything that scoped_array can, and then some.

If you want a rectangular array, I recommend using a unique_ptr<double[]> to hold the main data and a unique_ptr<double*[]> to hold the row bases. This would work something like this:

unique_ptr<double[]> data{ new double[5*3] };
unique_ptr<double*[]> rows{ new double*[3] };
rows[0] = data.get();
for ( size_t i = 1; i!=5; ++i )
    rows[i] = rows[i-1]+3;

Then you can pass rows.get() to a function taking double**. This approach can work for a non-rectangular array as well, provided the geometry of the array is known at array creation time so that you can allocate all the data at once and point rows to the proper offsets. (It may not be as straightforward as a simple loop, though.)

This will also give you better locality of reference and memory usage, since you only perform two allocations. All of your data will be stored together in memory and there won't be additional overhead for the separate allocations.

If you want to change the geometry of the jagged array after creating it, you will need to come up with a principled way of managing the storage for this solution to be applicable. However, since changing the geometry using scoped_array is awkward (requiring specific uses of swap()), I wouldn't be surprised if this isn't an issue for you.

(Note that this approach can work with scoped_array as well as unique_ptr<[]>; I'm simply illustrating it using unique_ptr since we're in C++11 now.)

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