While Jon Skeet's answer is an excellent advice for everyday's practice with small to moderate number of elements (up to a few millions) it is nevertheless not the fastest approach and not very resource efficient. An obvious drawback is the fact that getting the full difference requires two passes over the data (even three if the elements that are equal are of interest as well). Clearly, this can be avoided by a customized reimplementation of the `Except`

method, but it remains that the creation of a hash set requires a lot of memory and the computation of hashes requires time.

For very large data sets (in the billions of elements) it usually pays off to consider the particular circumstances. Here are a few ideas that might provide some inspiration:
If the elements can be compared (which is almost always the case in practice), then sorting the lists and applying the following zip approach is worth consideration:

```
/// <returns>The elements of the specified (ascendingly) sorted enumerations that are
/// contained only in one of them, together with an indicator,
/// whether the element is contained in the reference enumeration (-1)
/// or in the difference enumeration (+1).</returns>
public static IEnumerable<Tuple<T, int>> FindDifferences<T>(IEnumerable<T> sortedReferenceObjects,
IEnumerable<T> sortedDifferenceObjects, IComparer<T> comparer)
{
var refs = sortedReferenceObjects.GetEnumerator();
var diffs = sortedDifferenceObjects.GetEnumerator();
bool hasNext = refs.MoveNext() && diffs.MoveNext();
while (hasNext)
{
int comparison = comparer.Compare(refs.Current, diffs.Current);
if (comparison == 0)
{
// insert code that emits the current element if equal elements should be kept
hasNext = refs.MoveNext() && diffs.MoveNext();
}
else if (comparison < 0)
{
yield return Tuple.Create(refs.Current, -1);
hasNext = refs.MoveNext();
}
else
{
yield return Tuple.Create(diffs.Current, 1);
hasNext = diffs.MoveNext();
}
}
}
```

This can e.g. be used in the following way:

```
const int N = <Large number>;
const int omit1 = 231567;
const int omit2 = 589932;
IEnumerable<int> numberSequence1 = Enumerable.Range(0, N).Select(i => i < omit1 ? i : i + 1);
IEnumerable<int> numberSequence2 = Enumerable.Range(0, N).Select(i => i < omit2 ? i : i + 1);
var numberDiffs = FindDifferences(numberSequence1, numberSequence2, Comparer<int>.Default);
```

Benchmarking on my computer gave the following result for N = 1M:

Method |
Mean |
Error |
StdDev |
Ratio |
Gen 0 |
Gen 1 |
Gen 2 |
Allocated |

DiffLinq |
115.19 ms |
0.656 ms |
0.582 ms |
1.00 |
2800.0000 |
2800.0000 |
2800.0000 |
67110744 B |

DiffZip |
23.48 ms |
0.018 ms |
0.015 ms |
0.20 |
- |
- |
- |
720 B |

And for N = 100M:

Method |
Mean |
Error |
StdDev |
Ratio |
Gen 0 |
Gen 1 |
Gen 2 |
Allocated |

DiffLinq |
12.146 s |
0.0427 s |
0.0379 s |
1.00 |
13000.0000 |
13000.0000 |
13000.0000 |
8589937032 B |

DiffZip |
2.324 s |
0.0019 s |
0.0018 s |
0.19 |
- |
- |
- |
720 B |

Note that this example of course benefits from the fact that the lists are already sorted and integers can be very efficiently compared. But this is exactly the point: If you do have favourable circumstances, make sure that you exploit them.

A few further comments: The speed of the comparison function is clearly relevant for the overall performance, so it may be beneficial to optimize it. The flexibility to do so is a benefit of the zipping approach. Furthermore, parallelization seems more feasible to me, although by no means easy and maybe not worth the effort and the overhead. Nevertheless, a simple way to speed up the process by roughly a factor of 2, is to split the lists respectively in two halfs (if it can be efficiently done) and compare the parts in parallel, one processing from front to back and the other in reverse order.

away, but thequickestway.