# Determine least common ancestor at compile-time

There are tons of questions about the least common ancestor algorithm, but this one is different because I'm trying to determine the LCA at compile-time, and my tree is neither binary nor a search tree, even though my simplified version may look like one.

Suppose you have a bunch of structures which contain a member typedef `parent`, which is another similar structure:

``````struct G
{
typedef G parent;    // 'root' node has itself as parent
};

struct F
{
typedef G parent;
};

struct E
{
typedef G parent;
};

struct D
{
typedef F parent;
};

struct C
{
typedef F parent;
};

struct B
{
typedef E parent;
};

struct A
{
typedef E parent;
};
``````

which together make a tree such as

``````A    B    C    D
\  /      \  /
E         F
\       /
\     /
\   /
G
``````

NOTE: There is no inheritance relationship between the structures.

What I would like to do is create a type-trait `least_common_ancestor` such that:

``````least_common_ancestor<A, B>::type;    // E
least_common_ancestor<C, D>::type;    // F
least_common_ancestor<A, E>::type;    // E
least_common_ancestor<A, F>::type;    // G
``````

What's the best way to do this?

I'm not concerned with algorithmic complexity particularly since the tree depth is small, rather I'm looking for the simplest meta-program that that will get to the correct answer.

EDIT: I need to be able to build the solution with msvc2013, among other compilers, so answers without `constexpr` are preferred.

This may probably be improved, but you could first compute the depth of your type and then use this information to go up one branch or the other:

``````template <typename U, typename = typename U::parent>
struct depth {
static const int value = depth<typename U::parent>::value + 1;
};

template <typename U>
struct depth<U, U> {
static const int value = 0;
};
``````

The above will basically compute the depth of your type in your tree.

Then you could use `std::enable_if`:

``````template <typename U, typename V, typename Enabler = void>
struct least_common_ancestor;

template <typename U>
struct least_common_ancestor<U, U> {
using type = U;
};

template <typename U, typename V>
struct least_common_ancestor<U, V,
typename std::enable_if<(depth<U>::value < depth<V>::value)>::type> {
using type = typename least_common_ancestor<U, typename V::parent>::type;
};

template <typename U, typename V>
struct least_common_ancestor<U, V,
typename std::enable_if<(depth<V>::value < depth<U>::value)>::type> {
using type = typename least_common_ancestor<V, typename U::parent>::type;
};

template <typename U, typename V>
struct least_common_ancestor<U, V,
typename std::enable_if<!std::is_same<U, V>::value && (depth<V>::value == depth<U>::value)>::type> {
using type = typename least_common_ancestor<typename V::parent, typename U::parent>::type;
};
``````

Output:

``````int main(int, char *[]) {

std::cout << std::is_same<least_common_ancestor<A, B>::type, E>::value << std::endl;
std::cout << std::is_same<least_common_ancestor<C, D>::type, F>::value << std::endl;
std::cout << std::is_same<least_common_ancestor<A, E>::type, E>::value << std::endl;
std::cout << std::is_same<least_common_ancestor<A, F>::type, G>::value << std::endl;
std::cout << std::is_same<least_common_ancestor<A, A>::type, A>::value << std::endl;

return 0;
}
``````

Gives:

``````1 1 1 1 1
``````

This may probably be improved but could be used as a starting point.

• Sorry, I should have mentioned I'm building on msvc2013 which doesn't support `constexpr`. – Nicolas Holthaus Apr 11 '16 at 15:16
• @NicolasHolthaus You can replace `constexpr` with `const` in this case, it was just cleaner for me. I have updated the answer. – Holt Apr 11 '16 at 15:16
• Thanks, I'm testing it out. Visual Studio is also weird about how it chooses template specializations since it doesn't do two-phase lookup so I'll probably have to re-factor the `enable_if` statements before I know if it will work. – Nicolas Holthaus Apr 11 '16 at 15:23
• @NicolasHolthaus I cannot test it right now with msvc 2013, but it looks like it works with msvc 2015 (rextester.com/l/cpp_online_compiler_visual). – Holt Apr 11 '16 at 15:29
• It worked out of the box . Thanks! – Nicolas Holthaus Apr 11 '16 at 16:45
``````template <typename...> struct typelist {};

template <typename T, typename... Ts>
struct path : path<typename T::parent, T, Ts...> {};

template <typename T, typename... Ts>
struct path<T, T, Ts...> { using type = typelist<T, Ts...>; };

template <typename T, typename U>
struct least;

template <typename T, typename... Vs, typename... Us>
struct least<typelist<T, Vs...>, typelist<T, Us...>> { using type = T; };

template <typename T, typename W, typename... Vs, typename... Us>
struct least<typelist<T, W, Vs...>, typelist<T, W, Us...>>
: least<typelist<W, Vs...>, typelist<W, Us...>> {};

template <typename V, typename U>
using least_common_ancestor = least<typename path<V>::type, typename path<U>::type>;
``````

DEMO

1. Bottom-up: Form paths (`path::type`) from both nodes to the root by means of prepending a typelist at each level (`path<?, T, Ts...>`), until `parent` equals the currently processed node (`<T, T, ?...>`). Moving upwards is performed by replacing `T` by `T::parent`.

2. Top-down: Descend the two typelists simultaneously (`least`), until there's a mismatch at corresponding positions (`Vs..., Us...`); if so, the last common node is the common ancestor (`T`); otherwise (`<T, W, ?...>, <T, W, ?...>`), remove the matching node (`T`) and step one level down (now `W` is the last known common node).

• Well, maybe a short description would help, but it's good. – skypjack Apr 11 '16 at 16:27

This is probably not the most algorithmically efficient approach, but it's functional.

First, we're going to create lists out of the ancestors of each type. So for `A` this would be `<A,E,G>` and for `G` this would be `<G>`:

``````template <class X>
using parent_t = typename X::parent;

template <class... > struct typelist {};
template <class T> struct tag_t { using type = T; };

template <class, class> struct concat;
template <class X, class Y> using concat_t = typename concat<X, Y>::type;

template <class... Xs, class... Ys>
struct concat<typelist<Xs...>, typelist<Ys...>>
: tag_t<typelist<Xs..., Ys...>>
{ };

template <class X, class = parent_t<X>>
struct ancestors
: tag_t<concat_t<typelist<X>, typename ancestors<parent_t<X>>::type>>
{ };

template <class X>
struct ancestors<X, X>
: tag_t<typelist<X>>
{ };

template <class X>
using ancestors_t = typename ancestors<X>::type;
``````

Then the least common ancestor of two nodes is just going to be the first node in one node's ancestors that is contained in the other node's ancestors:

``````template <class X, class TL> struct contains;
template <class X, class TL> using contains_t = typename contains<X, TL>::type;

template <class X, class... Xs>
struct contains<X, typelist<X, Xs...>> : std::true_type { };

template <class X, class Y, class... Xs>
struct contains<X, typelist<Y, Xs...>> : contains_t<X, typelist<Xs...>> { };

template <class X>
struct contains<X, typelist<>> : std::false_type { };

template <class X, class Y>
struct lca_impl;

template <class X, class Y>
struct lca : lca_impl<ancestors_t<X>, ancestors_t<Y>> { };

template <class X, class... Xs, class TL>
struct lca_impl<typelist<X, Xs...>, TL>
: tag_t<
typename std::conditional_t<contains_t<X, TL>::value,
tag_t<X>,
lca_impl<typelist<Xs...>, TL>
>::type
>
{ };

template <class X, class Y>
using lca_t = typename lca<X, Y>::type;
``````

which has the behavior you'd expect:

``````static_assert(std::is_same<lca_t<A, E>, E>{}, "!");
static_assert(std::is_same<lca_t<A, D>, G>{}, "!");
``````
• @Downvoter What's up? This does work. – Barry Apr 11 '16 at 15:20