I will ask an obvious question, but it really changes *everything*:

Is the notion of equality in the `map`

compatible with the notion of equality in the `unordered_map`

?

As an example of incompatible definitions:

```
struct Point3D { std::int32_t x, y, z };
struct MapLess {
bool operator()(Point3D const& left, Point3D const& right) const {
return std::tie(left.x, left.y) < std::tie(right.x, right.y);
}
};
bool operator==(Point3D const& left, Point3D const& right) {
return std::tie( left.x, left.z)
== std::tie(right.x, right.z);
}
```

In this (contrived) case, we could have:

`map`

: `(1, 2, 3)`

and `(1, 3, 3)`

`unordered_map`

: `(1, 2, 3)`

and `(1, 2, 4)`

and a naive look-up would report that the `map`

is included in the `unordered_map`

which since they both have the same size would lead to the erroneous conclusion that they are equal.

The solution if a canonical notion of equality exists is to verify, after each look-up, that the look-up result is effectively the same as the original.

```
template <typename M1, typename M2>
bool equal(M1 const& left, M2 const& right) {
if (left.size() != right.size()) { return false; }
for (auto const& e: left) {
auto const it = right.find(e.first);
if (it == right.end()) { return false; }
if (it->first != e.first) { return false; }
if (it->second != e.second) { return false; }
}
return true;
}
```

*Note: this could be rewritten with *`std::all`

and a single boolean expression; it's a matter of taste, I prefer breaking it down.

If no canonical notion of equality exists, then a reverse look-up can replace the equality check:

```
template <typename M1, typename M2>
bool equal(M1 const& left, M2 const& right) {
if (left.size() != right.size()) { return false; }
for (auto e = left.begin(), end = left.end(); e != end; ++e) {
auto const it = right.find(e->first);
if (it != right.end()) { return false; }
if (left.find(it->first) != e) { return false; }
if (it->second != e->second) { return false; }
}
return true;
}
```

This is of course slightly more expensive.