```
#include <cassert>
#include <vector>
using namespace std;
template<typename Type, int Dimension>
const vector<Type> make_fixed_vector(const Type& value = Type())
{
return vector<Type>(Dimension, value);
}
int main(void)
{
vector<int> v3 = make_fixed_vector<int, 3>();
assert(v3.size() == 3);
}
```

C++1x compilers are able to deduce the type of a variable, which is handy when declaring multi-dimensional "fixed" vectors using this technique:

```
.
.
.
template<typename Type, int Rows, int Columns>
const vector<vector<Type> > make_fixed_vector_vector(const Type& value = Type())
{
return vector<vector<Type> >(Rows, make_fixed_vector<Type, Columns>(value));
}
int main(void)
{
auto vv = make_fixed_vector_vector<int, 3, 4>(42);
assert(vv.size() == 3);
assert(vv[0].size() == 4);
assert(vv[0][0] == 42);
assert(vv[2][3] == 42);
}
```

I had this simple idea when programming a parser-function for list expressions which shall return a fixed-size vector of vector of integers. For example, a `vector<vector<int> >(1)`

for a expression like "(0,8)", but a `vector<vector<int> >(2)`

for a expression like "(3-4)(5)" and so on. In the application up to 5 parenthesized definitions are possible, which represent logical references to program data. I first try to parse a `vector<vector<int> >(5)`

. Worked? Ok, got reference type A, the most detailed one. Otherwise `vector<vector<int> >(4)`

indicates a reference type B etc.

For this purpose `make_fixed_vector`

worked well, but from a general perspective the technique has flaws. Most notably, since `make_fixed_vector`

returns no true type, its dimension(s) cannot be checked at compile-time. At runtime `reserve`

, `resize`

and `push_back`

calls are possible. And, since function templates cannot have default template arguments, custom allocators require more typing:

```
template<typename Type, int Dimension, template<typename> class Allocator>
const vector<Type Allocator<Type> > make_fixed_vector(const Type& value = Type())
{
return vector<Type, Allocator<Type> >(Dimension, value);
}
vector<int> v3 = make_fixed_vector<int, 3, std::allocator>();
```

etc. etc. But this technique keeps smaller projects basic. Unless this virtue is relevant Boost's `boost::array`

might be more realistic.

`error: cannot convert 'double*' to 'double (*)[3]' in initialization`

. – Lightness Races in Orbit Mar 23 '11 at 13:48