**C# code snippet**

```
var dict = new Dictionary<int, HashSet<List<int>>>();
foreach (List<int> list2 in two) {
foreach (int i in list2) {
if(dict.ContainsKey(i) == FALSE) {
//create empty HashSet dict[i]
dict.Add(i, new HashSet<List<int>>());
}
//add reference to list2 to the HashSet dict[i]
dict[i].Add(list2);
}
}
foreach (List<int> list1 in one) {
HashSet<List<int>> listsInTwoContainingList1 = null;
foreach (int i in list1) {
if (listsInTwoContainingList1 == null) {
listsInTwoContainingList1 = new HashSet<List<int>>(dict[i]);
} else {
listsInTwoContainingList1.IntersectWith(dict[i]);
}
if(listsInTwoContainingList1.Count == 0) { //optimization :p
break;
}
}
foreach (List<int> list2 in listsInTwoContainingList1) {
//list2 contains list1
//do something
}
}
```

**Example**

```
L2= {
L2a = {10, 20, 30, 40}
L2b = {30, 40, 50, 60}
L2c = {10, 25, 30, 40}
}
L1 = {
L1a = {10, 30, 40}
L1b = {30, 25, 50}
}
```

After the first part of the code:

```
dict[10] = {L2a, L2c}
dict[20] = {L2a}
dict[25] = {L2c}
dict[30] = {L2a, L2b, L2c}
dict[40] = {L2a, L2b, L2c}
dict[50] = {L2c}
dict[60] = {L2c}
```

In the second part of the code:

```
L1a: dict[10] n dict[30] n dict[40] = {L2a, L2c}
L1b: dict[30] n dict[25] n dict[50] = { }
```

So `L1a`

is included in `L2a`

and `L2c`

, but `L1b`

in none.

**Complexity**

Now regarding the algorithm complexity, suppose `L1`

has `n1`

elements, `L2`

has `n2`

elements, the average number of elements of the sublists of `L1`

is `m1`

and the average number of elements of the sublists of `L2`

is `m2`

. Then:

the original solution is:
`O(n1 x n2 x m1 x m2)`

, if the *containsSetOf* method does a nested loop, or, at best, `O(n1 x n2 x (m1 + m2))`

, if it uses a HashSet. Is7aq's solution is also `O(n1 x n2 x (m1 + m2))`

.

the proposed solution is:
`O(n2 x m2 + n1 x (m1 x nd + n2))`

, where `nd`

is the average number of elements of the sets `dict[i]`

.

The efficiency of the proposed solution depends a lot on this `nd`

:

If `nd`

is large - close to `n2`

(when every integer is part of every sublist of `L2`

), then it is just as slow as the original one.

However, if `nd`

is expected to be small (i.e. the sublists of `L2`

are quite different from one another), then the proposed solution would typically be much faster, especially if `n1`

and `n2`

are large.