# dynamical two dimension array according to input

I need to get an input N from the user and generate a N*N matrix. How can I declare the matrix? Generally, the size of the array and matrix should be fixed at the declaration, right? What about `vector<vector<int>>` ? I never use this before so I need suggestion from veteran.

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Dynamic multi-dimensional arrays in [c] have been discussed several times, and that style is available as well. –  dmckee Feb 7 '10 at 16:51

Boost implements matrices (supporting mathematical operations) in its uBLAS library, and provides usage syntax like the following.

``````#include <boost/numeric/ublas/matrix.hpp>

int main(int argc, char* argv[])
{
unsigned int N = atoi(argv[1]);
boost::matrix<int> myMatrix(N, N);

for (unsigned i = 0; i < myMatrix.size1 (); ++i)
for (unsigned j = 0; j < myMatrix.size2 (); ++j)
myMatrix(i, j) = 3 * i + j;

return 0;
}
``````
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A `vector<vector<int> >` (note the space in the `> >`) can work well, but it's not necessarily the most efficient way to do things. Another that can work quite nicely is a wrapper around a single vector, that keeps track of the "shape" of the matrix being represented, and provides a function or overloaded operator to access the data:

``````template <class T>
class matrix {
int columns_;
std::vector<T> data;
public:
matrix(int columns, int rows) : columns_(columns), data(columns*rows) {}

T &operator()(int column, int row) { return data[row*columns_+column]; }
};
``````

Note that the C++ standard only allows `operator[]` to take a single operand, so you can't use it for this job, at least directly. In the example above, I've (obviously enough) used `operator()` instead, so subscripts look more like Fortran or BASIC than you're accustomed to in C++. If you're really set on using `[]` notation, you can do it anyway, though it's mildly tricky (you overload it in the matrix class to return a proxy, then have the proxy class also overload `operator[]` to return (a reference to) the correct element -- it's mildly ugly internally, but works perfectly well anyway).

Edit: Since I have it lying around, here's an example of how to implement the latter. I wrote this (quite a while) before most compilers included `std::vector`, so it statically allocates an array instead of using a vector. It's also for the 3D case (so there are two levels of proxies involved), but with a bit of luck, the basic idea comes through anyway:

``````template<class T, int size>
class matrix3 {

T data[size][size][size];

friend class proxy;
friend class proxy2;

class proxy {
matrix3 &m_;
int index1_, index2_;
public:
proxy(matrix3 &m, int i1, int i2)
: m_(m), index1_(i1), index2_(i2)
{}

T &operator[](int index3) {
return m_.data[index1_][index2_][index3];
}
};

class proxy2 {
matrix3 &m_;
int index_;
public:
proxy2(matrix3 &m, int d) : m_(m), index_(d) { }

proxy operator[](int index2) {
return proxy(m_, index_, index2);
}
};
public:
proxy2 operator[](int index) {
return proxy2(*this, index);
}
};
``````

Using this, you can address the array with the normal C++ syntax, such as:

``````matrix3<double, size> m;

for (int x=0; x<size; x++)
for (int y = 0; y<size; y++)
for (int z = 0; z<size; z++)
m[x][y][z] = x*100 + y * 10 + z;
``````
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Care to shed some light on the inefficiency part of vector of vectors? –  Murali VP Feb 7 '10 at 5:35
@Murali:basically, you've got inefficiency in a couple of ways. First of all, even though all the sub-vectors (so to speak) are going to be the same size, each one stores its own length. Second, a vector is (at least normally) implemented using a pointer to dynamically allocated data, so with a vector of vectors, you need to go through two levels of pointers to get to the real data. Using a single vector involves multiplication instead, which was once a bad tradeoff, but with CPUs faster than memory, it's now almost always a win (extra CPU time vs. possibility of extra memory access). –  Jerry Coffin Feb 7 '10 at 5:45
You could also use std::valarray since it already supports a variety of subset access mechanisms. –  MSN Feb 7 '10 at 6:31
@MSN:You could -- `valarray` is something I've mentioned a few times in the past, but frankly that's a banner I've decided to quit waving, so to speak. Simple uses of it might make sense, but the minute you get into slice, gslice, slice_array, etc., it becomes completely opaque to at least 99% of the C++ community. Worse, it was really designed for vector processors; it's relatively cache unfriendly, so even if you know what it's doing, and a reader does as well, it'll often be quite an inefficient way of doing it anyway. –  Jerry Coffin Feb 7 '10 at 16:26
but think about all the typing you would save! :) –  MSN Feb 7 '10 at 18:34