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I was trying to make a function which takes a matrix as input and outputs some function of it in C++. But I want it to work on arbitrary size mxn matrix. i.e. I cannot specify in the arguments of the function the values of n (double matrix[][n]) . Because n will be arbitrary. Is there any way I can pass on an arbitrary mxn 2 dimensional array to a function? Thanking you in advance. -indiajoe

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Thanks for the boost Library links.. – indiajoe Mar 1 '11 at 19:30
up vote 7 down vote accepted
template <typename T, size_t W, size_t H>
void foo(T (&array)[W][H]) {
   // Do stuff with array here
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How about dynamic matrix allocation ? – Eric Fortin Mar 1 '11 at 16:44
@Eric: Why? It's not needed. The OP wanted a way to pass around a two-dimensional array with arbitrary dimensions, and here it is! – Lightness Races in Orbit Mar 1 '11 at 16:55
If the code of the function is large, it can cause huge increase of the application code size if called with lots of different size of matrix. Not every compiler is smart enough to merge template function. – Sylvain Defresne Mar 1 '11 at 17:33
@Sylvain: It was not specified in the question that the code should be optimised for executable size. Perhaps it should be optimised for legibility, maintainability and ease of use, in which case this is the solution. (Did you like my clever avoidance? :P) – Lightness Races in Orbit Mar 1 '11 at 17:40
@Sylvain - yes, this code causes a lot of superfluous specializations. Better to use the iterator approach if you need to use template code. It would still be specialized on column count, but at least not on row count too. Iterator approach also has the benefit of being more legible. – Crazy Eddie Mar 1 '11 at 17:42

There is more than one way to do it. The best way is probably to define a matrix class and to pass a const reference to an instance.

class matrix
    double* values;
    size_t m;
    size_t n;
    matrix(size_t m_, size_t n_)
    : m(m_), n_(n)
        values = new double[m * n];

        delete[] values;

    double& operator(size_t i, size_t j)
        assert(i < m);
        assert(j < n);
        return values[i + m * j];

    const double& operator(size_t i, size_t j) const
        assert(i < m);
        assert(j < n);
        return values[i + m * j];
    matrix(const matrix&);
    matrix& operator =(const matrix&);

void function(const matrix& matrix);

If you don't want to use a class, and your data is stored linearly (as in my matrix class), you can simply pass a pointer to a double, and the dimensions:

void function(double* values, size_t m, size_t n);

If you really want to use double[m][n] and have a function accepting any matrix size, you can convert it manually to a double**, by doing something like that:

void function(double** lines, size_t m, size_t n);

void client()
    const size_t m = ...;
    const size_t n = ...;
    double matrix[m][n];

    double* temporary[m];
    for (size_t i = 0; i < m; ++ i) {
        temporary[i] = &matrix[i][0];

    function(temporary, m, n);

Or, using a template function to do the conversion:

void function(double** array, size_t m, size_t n);

template < size_t M, size_t N >
void function(double array[M][N]) {
    double* temporary[M];
    for (size_t i = 0; i < M; ++ i) {
        temporary[i] = &array[i][0];
    function(temporary, M, N);

This is because an array can only decay once to a pointer (that is double[n] decay to double* but double[m][n] decay to double*[n]).

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Your second suggestion to collapse 2d matrix into a 1d array of pointers, seems to be the simplest solution for my problem. Thanks a lot to everyone for all the various ways to do it. – indiajoe Mar 1 '11 at 19:22

using the Standard C++ Library, you could do that:

typedef std::vector<double> Dim;
typedef std::vector<Dim> Matrix;

void workOnMatrix(Matrix& matrix)


EDIT: I remove the reference to STL since SGI's STL and the Standard C++ Library are not the same things. So much different it seems that they must not be taken one for another.

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resists urge to go on "STL" rant – Lightness Races in Orbit Mar 1 '11 at 16:37
I dislike C-style coding, so going STL is no problem for me ;) – Stephane Rolland Mar 1 '11 at 16:56
This is a much better solution than Tomalak's. – Crazy Eddie Mar 1 '11 at 17:21
I imagine the rant was about confusing the C++ Standard Library and the STL -- STL was a pre-standard library that was partially incorporated into the C++ Standard Library; they're not the same thing (despite all-too-common usage). – Stuart Golodetz Mar 1 '11 at 17:22
@Tomalak - "Think outside your bubble please." <- That's a might bit rude. Just because I disagree with you doesn't mean I'm in a bubble. Newcomers are not confused by applying the term STL to the parts of the standard library that have that historical root. – Crazy Eddie Mar 1 '11 at 17:49

You could do it Tomalak's way, but I certainly wouldn't recommend it. You could never call that function from within another that wasn't also a template if the array was passed through params. This means almost your entire program would have to be templated code. OK, in theory, but generally impractical.

You can't use the double** interface as you've found out. You could cast to that type but then you also need the size information to be passed in so that you can:

my_ptrptr[row * col_size][col];

You have to be explicit about the dimensions like this because the compiler no longer knows what it needs to.

The best answer to your problem is to not do it that way. Leverage the STL so that you don't have to deal with hokey crap like this. Use Stephane's answer.

Yet another thing you can do though, if you're going to use templates anyway, is to write it to be generic:

template < typename Iter >
void fun(Iter begin, Iter end)
  // begin[x][y]... (*begin)[y]...++begin, etc...
double arr[arr_row_count][arr_col_count];
fun(arr, arr+arr_row_count);

This one has the major benefit of working with ANYTHING that looks like an array of arrays. This means it would make an excellent 'interim' method that you can use with your double[][] types until such time as you can begin using something better like the std::vector and/or boost::array. Do it Tomalak's way and you won't be able to make this change later...yet another reason not to use that method.

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"You could never call that function from within another that wasn't also a template if the array was passed through params." Well, that's complete nonsense. What on earth makes you think that? Are you actually talking about arrays whose dimensions are only known at runtime? Because my answer was, of course, about normal statically-allocated arrays, and my function can be used from any context in code. – Lightness Races in Orbit Mar 1 '11 at 17:47

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