It's hard to implement this efficiently with a `SortedDictionary<TKey, TValue>`

since it is implemented as a binary search tree that does not expose predecessors or successors.

You could of course just enumerate each KeyValuePair until you find the "known" key. With a little bit of LINQ, this would look like (assuming the key definitely exists and isn't the first key):

```
SortedDictionary<int, int> dictionary = ...
int knownKey = ...
var previousKvp = dictionary.TakeWhile(kvp => kvp.Key != knownKey)
.Last();
```

If those assumptions don't hold, you could do:

```
var maybePreviousKvp = dictionary.TakeWhile(kvp => kvp.Key != knownKey)
.Cast<KeyValuePair<int, int>?>()
.LastOrDefault();
```

(Check that `maybePreviousKvp != null`

to ascertain that the previous KeyValuePair was retrieved successfully.)

But this isn't going to be efficient at all.

If feasible, consider using a `SortedList<TKey, TValue>`

instead (obviously, this may not be possible if you can't take its slower inserts and deletes). This collection supports efficient key and value-retrieval by *ordered* index since it is implemented as a growable array. Then your query becomes as simple as:

```
SortedList<int, int> dictionary = ...
int knownKey = ...
int indexOfPrevious = dictionary.IndexOfKey(knownKey) - 1;
// if "known" key exists and isn't the first key
if(indexOfPrevious >= 0)
{
// Wrap these in a KeyValuePair if necessary
int previousKey = dictionary.Keys[indexOfPrevious];
int previousValue = dictionary.Values[indexOfPrevious];
}
```

`IndexOfKey`

runs a binary search on the keys-list, running in `O(log n)`

time. Everything else should run in constant time, meaning the entire operation should run in logarithmic time.

Otherwise, you'll have to implement yourself / find a BST collection that does expose predecessors / successors.