# Binary Search on Keys of SortedList<K, V>

I need to write some code for linear interpolation and I am trying to figure out the most efficient way to search the Keys of a `SortedList<K, V>` for the upper and lower keys that surround my target key.

``````SortedList<int, double> xyTable = new SortedList<int, double>()
{
{1, 10}, {2, 20}, {3, 30}, {4,40}
};

double targetX = 3.5;
``````

What is the most efficient way to search the list and determine that 3.5 is between 3 and 4? I have a method / cheat that works for integers (temporarily insert the target Key into the list then find the index) but I figured I'd ask the pros so I could produce quality code.

Thanks.

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sorted sounds perfect for binary search –  Marc May 23 '11 at 19:24

In my case the source `SortedList` is not changing much, since its being used as a lookup table. So in this case it makes sense to convert the `SortedList` to a `List<T>` once. After that it is quite easy to use the built-in BinarySearch method of `List<T>`...

``````double targetX = 3.5;

// Assume keys are doubles, may need to convert to doubles if required here.
List<double> keys = xyTable.Keys.ToList();

int ipos = keys.BinarySearch(targetX);

if (ipos >= 0)
{
// exact target found at position "ipos"
}
else
{
// of the next index in the list larger than the target.
ipos = ~ipos;
if (ipos >= 0 && ipos < keys.Count)
{
if (ipos > 0)
{
// target is between positions "ipos-1" and "ipos"
}
else
{
// target is below position "ipos"
}
}
else
{
// target is above position "ipos"
}
}
``````
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Good stuff, this is the answer I was going to give you. :) –  Haney Jun 11 '14 at 13:35

A binary search gives you decent performance on a list. However the Keys property on `SortedList` is of type `IList`, whereas `BinarySearch` is defined on `List`. Fortunately, you can find an implementation of binary search for `IList` in this related question:

How to perform a binary search on IList<T>?

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This is my fav answer here :) Should have been built in on SortedList. –  nawfal Jun 14 '14 at 9:33
``````public class Bounds
{
int lower;
int upper;

public Bounds(int lower, int upper)
{
this.lower = lower;
this.upper = upper;
}
}

public Bounds BinarySearch(List<int> keys, double target)
{
// lower boundary case returns the smallest key as the lower and upper bounds
if (target < keys[0])
return new Bounds(0, 0);

else if (target < keys[1])
return new Bounds(0, 1);

// upper boundary case returns the largest key as the lower and upper bounds
else if (target > keys[keys.Length - 1])
return new Bounds(keys.Length - 1, keys.Length - 1);

else if (target > keys[keys.Length - 2])
return new Bounds(keys.Length - 2, keys.Length - 1);

else
return BinarySearch(keys, target, 0, keys.Length - 1);

}

// 'keys' is a List storing all of the keys from your SortedList.
public Bounds BinarySearch(List<int> keys, double target, int lower, int upper)
{
int middle = (upper + lower)/2;

// target is equal to one of the keys
if (keys[middle] == target)
return new Bounds(middle - 1, middle + 1);

else if (keys[middle] < target && keys[middle + 1] > target)
return new Bounds(middle, middle + 1);

else if (keys[middle] > target && keys[middle - 1] < target)
return new Bounds(middle - 1, middle);

if (list[middle] < target)
return BinarySearch(list, target, lower, upper/2 - 1);

if (list[middle] > target)
return BinarySearch(list, target, upper/2 + 1, upper);
}
``````

This might work..I didn't test it out. If not, hopefully it's close enough that you can use it with minor tweaks. This is a strange problem, so I handled all of the boundary cases so I didn't have to think about what the algorithm would do when the range was down to 2 elements or less.

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Why not use `List<T>.BinarySearch()`? –  svick May 23 '11 at 20:41
I'm not very familiar with it..will the List<T>.BinarySearch() be sufficient for finding what he's looking for? –  alexD May 23 '11 at 20:45
it would be, if he hed `List<T>`, but he only has `IList<T>`, so your solution is a actually a good suggestion. –  svick May 23 '11 at 20:47

From MSDN,

The elements of a SortedList object are sorted by the keys either according to a specific IComparer implementation specified when the SortedList is created, or according to the IComparable implementation provided by the keys themselves. The index sequence is based on the sort sequence. When an element is added, it is inserted into SortedList in the correct sort order, and the indexing adjusts accordingly. When an element is removed, the indexing also adjusts accordingly. Therefore, the index of a specific key/value pair might change as elements are added or removed from the SortedList.

*****This method uses a binary search algorithm; therefore, this method is an O(log n) operation, where n is Count.*****

Starting with the .NET Framework 2.0, this method uses the collection’s objects’ Equals and CompareTo methods on item to determine whether item exists. In the earlier versions of the .NET Framework, this determination was made by using the Equals and CompareTo methods of the item parameter on the objects in the collection.

In other words, the method IndexOfKey in SortedList is actually using a binarySearch algorithm already, so there is no need to convert form SortedList to List in your case.

Hope it helps..

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