I have a function that takes a multidimensional std::vector and requires the depth (or the number of dimensions) to be passed in as a template parameter. Instead of hardcoding this value I would like to write a constexpr function that will take the std::vector and return the depth as an unsigned integer value.

For example:

std::vector<std::vector<std::vector<int>>> v =
    { { 0, 1}, { 2, 3 } },
    { { 4, 5}, { 6, 7 } },

// Returns 3
size_t depth = GetDepth(v);

This needs to be done at compile time though because this depth will be passed to the template function as a template parameter:

// Same as calling foo<3>(v);

Is there any way to do this?

  • 4
    The size of a std::vector is a run-time thing, not a compile-time one. If you want a compile-time size container, look to std::array. Also; remember that constexpr only means "may be evaluated at compile time" - there's no promise that it will be. It may be evaluated at run-time. Commented Dec 26, 2019 at 16:07
  • 6
    @JesperJuhl, I'm not looking for size, I'm looking for depth. Two very different things. I want to know how many std::vectors are nested within each other. For example with std::vector<std::vector<int>> v;, GetDepth(v); would return 2 since it is a 2 dimensional vector. The size is irrelevant.
    – tjwrona
    Commented Dec 26, 2019 at 16:09
  • 5
    Semi-related: nested vector isn't always the best way to do things. Manual 2d or 3d indexing of a single flat vector can be more efficient, depending on the use-case. (Just integer math instead of pointer-chasing from the outer levels.) Commented Dec 27, 2019 at 10:55
  • 2
    @PeterCordes Better efficiency is just one facet. Another one is that a flat type better represents the contiguous nature of the array. A nested structure (of potentially differing individual lengths) is fundamentally a type mismatch for representing a contiguous, n-dimensional hyperrectangle. Commented Dec 27, 2019 at 14:29
  • 5
    Nomenclature-wise the standard library uses rank for this query on array types (in agreement with the mathematical nomenclature for tensors). Perhaps that is a better word here than "depth". Commented Dec 27, 2019 at 20:19

3 Answers 3


A classic templating problem. Here's a simple solution like how the C++ standard library does. The basic idea is to have a recursive template that will count one by one each dimension, with a base case of 0 for any type that is not a vector.

#include <vector>
#include <type_traits>

template<typename T>
struct dimensions : std::integral_constant<std::size_t, 0> {};

template<typename T>
struct dimensions<std::vector<T>> : std::integral_constant<std::size_t, 1 + dimensions<T>::value> {};

template<typename T>
inline constexpr std::size_t dimensions_v = dimensions<T>::value; // (C++17)

So then you could use it like so:

dimensions<vector<vector<vector<int>>>>::value; // 3
// OR
dimensions_v<vector<vector<vector<int>>>>; // also 3 (C++17)


Ok, I've finished the general implementation for any container type. Note that I defined a container type as anything that has a well-formed iterator type as per the expression begin(t) where std::begin is imported for ADL lookup and t is an lvalue of type T.

Here's my code along with comments to explain why stuff works and the test cases I used. Note, this requires C++17 to compile.

#include <iostream>
#include <vector>
#include <array>
#include <type_traits>

using std::begin; // import std::begin for handling C-style array with the same ADL idiom as the other types

// decide whether T is a container type - i define this as anything that has a well formed begin iterator type.
// we return true/false to determing if T is a container type.
// we use the type conversion ability of nullptr to std::nullptr_t or void* (prefers std::nullptr_t overload if it exists).
// use SFINAE to conditionally enable the std::nullptr_t overload.
// these types might not have a default constructor, so return a pointer to it.
// base case returns void* which we decay to void to represent not a container.
template<typename T>
void *_iter_elem(void*) { return nullptr; }
template<typename T>
typename std::iterator_traits<decltype(begin(*(T*)nullptr))>::value_type *_iter_elem(std::nullptr_t) { return nullptr; }

// this is just a convenience wrapper to make the above user friendly
template<typename T>
struct container_stuff
    typedef std::remove_pointer_t<decltype(_iter_elem<T>(nullptr))> elem_t;    // the element type if T is a container, otherwise void
    static inline constexpr bool is_container = !std::is_same_v<elem_t, void>; // true iff T is a container

// and our old dimension counting logic (now uses std:nullptr_t SFINAE logic)
template<typename T>
constexpr std::size_t _dimensions(void*) { return 0; }

template<typename T, std::enable_if_t<container_stuff<T>::is_container, int> = 0>
constexpr std::size_t _dimensions(std::nullptr_t) { return 1 + _dimensions<typename container_stuff<T>::elem_t>(nullptr); }

// and our nice little alias
template<typename T>
inline constexpr std::size_t dimensions_v = _dimensions<T>(nullptr);

int main()
    std::cout << container_stuff<int>::is_container << '\n';                 // false
    std::cout << container_stuff<int[6]>::is_container<< '\n';               // true
    std::cout << container_stuff<std::vector<int>>::is_container << '\n';    // true
    std::cout << container_stuff<std::array<int, 3>>::is_container << '\n';  // true
    std::cout << dimensions_v<std::vector<std::array<std::vector<int>, 2>>>; // 3
  • What if I want this to work for all nested containers and not just vectors? Is there an easy way to make that happen?
    – tjwrona
    Commented Dec 26, 2019 at 16:17
  • @tjwrona1992 Ya, you could literally just copy and paste the std::vector<T> specialization and change it to some other container type. The only thing you need is the 0 base case for any type you don't specialize for
    – Cruz Jean
    Commented Dec 26, 2019 at 16:19
  • I meant without copy/paste haha, Like templating the template
    – tjwrona
    Commented Dec 26, 2019 at 16:19
  • @tjwrona1992 Oh, for that you would need to use SFINAE constexpr functions. I'll prototype a thing for that and add it as an edit.
    – Cruz Jean
    Commented Dec 26, 2019 at 16:20
  • @tjwrona1992, what is your definition of a container?
    – Evg
    Commented Dec 26, 2019 at 16:34

Assuming that a container is any type that has value_type and iterator member types (standard library containers satisfy this requirement) or a C-style array, we can easily generalize Cruz Jean's solution:

template<class T, typename = void>
struct rank : std::integral_constant<std::size_t, 0> {};

// C-style arrays
template<class T>
struct rank<T[], void> 
    : std::integral_constant<std::size_t, 1 + rank<T>::value> {};

template<class T, std::size_t n>
struct rank<T[n], void> 
    : std::integral_constant<std::size_t, 1 + rank<T>::value> {};

// Standard containers
template<class T>
struct rank<T, std::void_t<typename T::iterator, typename T::value_type>> 
    : std::integral_constant<std::size_t, 1 + rank<typename T::value_type>::value> {};

int main() {
    using T1 = std::list<std::set<std::array<std::vector<int>, 4>>>;
    using T2 = std::list<std::set<std::vector<int>[4]>>;

    std::cout << rank<T1>();  // Output : 4
    std::cout << rank<T2>();  // Output : 4

Container types can be further restricted if needed.

  • 1
    @CruzJean, sure. That's why I asked what a container is. Anyway, it can easily be fixed with an additional specialization, see the updated answer.
    – Evg
    Commented Dec 26, 2019 at 16:59
  • 2
    @Evg thank you. Today I learned about std::void_t! Brilliant!
    – marco6
    Commented Dec 27, 2019 at 12:53

You can define the following class template vector_depth<> which matches any type:

template<typename T>
struct vector_depth {
   static constexpr size_t value = 0;

This primary template corresponds to the base case that ends the recursion. Then, define its corresponding specialization for std::vector<T>:

template<typename T>
struct vector_depth<std::vector<T>> {
   static constexpr size_t value = 1 + vector_depth<T>::value;

This specialization matches an std::vector<T> and corresponds to the recursive case.

Finally, define the function template, GetDepth(), that resorts to the class template above:

template<typename T>
constexpr auto GetDepth(T&&) {
   return vector_depth<std::remove_cv_t<std::remove_reference_t<T>>>::value;


auto main() -> int {
   int a{}; // zero depth
   std::vector<int> b;
   std::vector<std::vector<int>> c;
   std::vector<std::vector<std::vector<int>>> d;

   // constexpr - dimension determinted at compile time
   constexpr auto depth_a = GetDepth(a);
   constexpr auto depth_b = GetDepth(b);
   constexpr auto depth_c = GetDepth(c);
   constexpr auto depth_d = GetDepth(d);

   std::cout << depth_a << ' ' << depth_b << ' ' << depth_c << ' ' << depth_d;

The output of this program is:

0 1 2 3
  • 1
    this works for std::vector, but e.g. GetDepth(v) where v is int won't compile. Would be better to have GetDepth(const volatile T&) and just return vector_depth<T>::value. volatile just lets it cover more stuff, being maximum cv qualified
    – Cruz Jean
    Commented Dec 31, 2019 at 19:31
  • @CruzJean Thanks for the suggestion. I've edited the answer. Commented Dec 31, 2019 at 19:43

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