For an embedded project, I want a class that takes a list of structs. This list is known at compile-time, so I shouldn't have to resort to dynamic memory allocation for this.

However, how do I make a struct/class that encapsulates this array without having to use its size as a template parameter?


My first idea was to do exactly that:

struct Point {
    const uint16_t a;
    const double b;

template<size_t n>
struct Profile {
    Array<Point, n> points;

    Profile(const Array<Point, n> &points) : points(points) {}

Here, Profile is the class that stores/encapsulates the array of points (the 2-member structs). n, the size of the array, is a template parameter.

I'm using this implementation of Array, similar to std::array, btw, because I don't have access to the STL on this embedded platform.

However, no I have another class that uses this Profile that now also has to be templated because Profile is templated with the size of the array:

template<size_t n>
class Runner {
    const Profile<n> profile;
    Runner(const Profile<n> &profile) : profile(profile) {};

    void foo() {
        for(auto point : profile.points) {
            // do something

As can be seen, this Runner class operates on a Profile and iterates over it. Having to template Runner is not that much of an issue by itself, but this Runner in turn is used by another class in my project, because this other class calls Runner::foo(). Now I have to template that class as well! And classes that use that class, etc.

That's getting out of hand! What started with just one template parameter to specify the size, now propagates through my entire application. Therefore, I don't think this is a good solution.


Is there a way to 'hide' the size of the array in Profile or Runner? Runner only needs to iterate over it, so the size should in principle only affect its implementation, not its public interface. How would I do that, though?

Also, can I avoid having to manually specify n at all, and just pass an array to Profile's constructor and let the compiler figure out how big it is? At compile-time, of course. I feel like this should be possible (given this array is known at compile-time), but I don't know how exactly.

Other approaches


I could write a macro like

#define n 12

and include that in both the Profile.h and the place where I instantiate a Profile. This feels dirty though, I and would like to avoid macros.


I could avoid this fuss by just using a std::vector (or equivalent) instead, but that is allocated at run-time on the heap, which I would like to avoid here since it shouldn't be necessary.

  • How many different sizes will you need? Jan 20, 2022 at 14:45
  • Also, this implementation of array seems to allow storing less than max elements (unlike std::array), perhpas it would be enough to just use the maximum size of the array you will ever use? Jan 20, 2022 at 14:51
  • 2
    At which point do you actually know the size of the array? If eg a Runner always needs a Profile with an array of size 12 then it can use Profile<12> if you need Runners with different sized Profiles then making Runner a template doesn't sound too bad Jan 20, 2022 at 14:57
  • @Yksisarvinen Don't really know yet. I just wanted a Profile class that works with an arbitrary size.
    – Compizfox
    Jan 20, 2022 at 15:01
  • 1
    What's the reason for not using a plain old array of size n where n is a plain old integer constant? Too easy? Too readable?
    – Lundin
    Jan 20, 2022 at 15:50

2 Answers 2


Is there a way to 'hide' the size of the array in Profile or Runner?

Yes. The solution is indirection. Instead of storing the object directly, you can point to it. You don't need to know the size of what you're pointing at.

A convenient solution is to point into dynamic storage (for example std::vector) because it allows you to "bind" the lifetime of the dynamically sized object to a member. That's not necessary in general, and you can use automatic storage instead. However, in that case you cannot bind the lifetime of the pointed object, and you must be very careful to not let the pointed object be destroyed before you stop using it.

The indirection can be done at whatever level you prefer. If you do it at the lowest level, you simply store the array outside of Profile. In fact, if all that profile does is contain an array, then you don't need a class for it. Use a generic span:

struct Runner {
    span<const Point> profile;
    void foo() {
        for(auto point : profile) {
            // do something

Point points[] {
    // ... number of points doesn't matter
Runner runner {
    .profile = points,

By span, I mean something like std::span. If you cannot use the standard library, then use another implementation. It's basically just a pointer and size, with convenient template constructor.

To clarify, you can pick any two, but you cannot have all three of these:

  1. Lifetime of the array bound to the class (safe)
  2. No compiletime constant size
  3. No dynamic storage
  • 1,2 (no 3) = std::vector, RAII
  • 1,3 (no 2) = std::array, templates, no indirection
  • 2,3 (no 1) = std::span, be careful with lifetimes
  • Thanks, this looks like a good solution! What is the reason this works? The fact that (unlike std::array) it doesn't make the size a part of its type ?
    – Compizfox
    Jan 20, 2022 at 15:21
  • 1
    @Compizfox It works because it's not trying to store the array inside the class. It's stored separately, with a separate lifetime.
    – eerorika
    Jan 20, 2022 at 15:22
  • I see. But even in my approach, I could ditch Profile as a container around the array (like you did) and only take/store a pointer/reference to the array in Runner. In that case, it doesn't store the array, yet it becomes part of Runner's type (leading to the exact same problem). With std::span, I avoid that, right?
    – Compizfox
    Jan 20, 2022 at 15:25
  • 1
    @Compizfox I could ditch Profile as a container around the array (like you did) and only take/store a pointer/reference to the array in Runner That's precisely what I'm suggesting as the solution (well not a reference since that wouldn't work). std::span is just a pointer and a size combined.
    – eerorika
    Jan 20, 2022 at 15:27
  • I got that, I was just dissecting why your solution works and mine didn't ;)
    – Compizfox
    Jan 20, 2022 at 15:38

I'll expand on this comment:

The idea is that Runner takes Profiles no matter their size. Runner needs to iterate over it, but apart from that, its behaviour is always the same. The class using Runner and calling Runner::foo() doesn't need to know the size. The problem with templating Runner is that the class using Runner also needs to be templated, and the classes using that, etc.

This is only a problem when the class is using the templated Runner directly. It has more dependencies than it actually needs. If it doesn't need to know about the size of the array, then it should not know about the size of the array. If runtime polymorphism is an option you can add a base class that allows accessing the array elements, but doesn't need to know anything about the arrays size. The following is only a sketch:

#include <iostream>

struct RunnerInterface {
    virtual int* begin() = 0;
    virtual int* end() = 0;
    virtual ~RunnerInterface(){}

template <unsigned size>
struct Runner : RunnerInterface {
    int data[size];
    int* begin() override { return data; }
    int* end() override { return data+size; } // pointer one past the end if fine (it won't get dereferenced)

void foo(RunnerInterface& ri) {
    for (auto it = ri.begin(); it != ri.end(); ++it){
        *it = 42;

void bar(RunnerInterface& ri){
    for (auto it = ri.begin(); it != ri.end(); ++it){
        std::cout << *it;

int main() {
    Runner<42> r;

Now if a class needs a Runner member, they store a std::unique_ptr<RunnerInterface> and only on construction you need to decide for the size of the array (though you still need to decide for the size somewhere).

  • I agree that the class using Runner shouldn't need to know about n. But with the template approach, this happens inevitably, right? The template parameter 'propagates'. Unless there is a way to 'break this chain' using type erasure or something. But I'm not sure about that. I would like to avoid runtime polymorphism.
    – Compizfox
    Jan 20, 2022 at 16:39

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