This may appear to be a duplicate of this question, which asks "What’s the difference between SortedList and SortedDictionary?" Unfortunately, the answers do nothing more than quote the MSDN documentation (which clearly states that there are performance and memory use differences between the two) but don't actually answer the question.

In fact (and so this question doesn't get the same answers), according to MSDN:

The SortedList<TKey, TValue> generic class is a binary search tree with O(log n) retrieval, where n is the number of elements in the dictionary. In this, it is similar to the SortedDictionary<TKey, TValue> generic class. The two classes have similar object models, and both have O(log n) retrieval. Where the two classes differ is in memory use and speed of insertion and removal:

  • SortedList<TKey, TValue> uses less memory than SortedDictionary<TKey, TValue>.

  • SortedDictionary<TKey, TValue> has faster insertion and removal operations for unsorted data, O(log n) as opposed to O(n) for SortedList<TKey, TValue>.

  • If the list is populated all at once from sorted data, SortedList<TKey, TValue> is faster than SortedDictionary<TKey, TValue>.

So, clearly this would indicated that SortedList<TKey, TValue> is the better choice unless you need faster insert and remove operations for unsorted data.

The question still remains, given the information above what are the practical (real-world, business case, etc.) reasons for using a SortedDictionary<TKey, TValue>? Based on the performance information, it would imply that there really is no need to have SortedDictionary<TKey, TValue> at all.

  • 1
    Note that the section you quote pretty much says it all. Note however that your statement about 'faster insert and remove operations for unsorted data' is not quite correct. What it is actually saying is that 'insert and remove' operations are always higher time-complexity on a SortedList. The statement about 'unsorted data' only relates to initialising these structures with data through their constructors.
    – jerryjvl
    Sep 4 '09 at 3:02
  • This appears to be relevant on .NET 2.0. The implementation of SortedList<TKey, TValue> seems to have changed from 3.0 onwards. I recently needed an answer to this question myself and found that this question and its responses may no longer be relevant for users of .NET 4.5.
    – Jeremy
    Mar 31 '15 at 2:37

I'm not sure how accurate the MSDN documentation is on SortedList and SortedDictionary. It seems to be saying both are implemented using a binary search tree. But if the SortedList uses a binary search tree, why would it be much slower on additions than SortedDictionary?

Anyway, here are some performance test results.

Each test operates on a SortedList / SortedDictionary containing 10,000 int32 keys. Each test is repeated 1,000 times (Release build, Start without Debugging).

The first group of tests add keys in sequence from 0 to 9,999. The second group of tests add random shuffled keys between 0 to 9,999 (every number is added exactly once).

***** Tests.PerformanceTests.SortedTest

SortedDictionary Add sorted: 4411 ms
SortedDictionary Get sorted: 2374 ms

SortedList Add sorted: 1422 ms
SortedList Get sorted: 1843 ms

***** Tests.PerformanceTests.UnsortedTest

SortedDictionary Add unsorted: 4640 ms
SortedDictionary Get unsorted: 2903 ms

SortedList Add unsorted: 36559 ms
SortedList Get unsorted: 2243 ms

As with any profiling, the important thing is the relative performance, not the actual numbers.

As you can see, on sorted data the sorted list is faster than the SortedDictionary. On unsorted data the SortedList is slightly quicker on retrieval, but about 9 times slower on adding.

If both are using binary trees internally, it is quite surprising that the Add operation on unsorted data is so much slower for SortedList. It is possible that sorted list may also be adding items to a sorted linear data structure at the same time, which would slow it down.

However, you would expect the memory usage of a SortedList to be equal or greater than or at least equal to a SortedDictionary. But this contradicts what the MSDN documentation says.

  • 4
    Their complexity bounds would be consistent with an implementation of SortedList using an array. Then lookups would be performed using a binary search in O(log n). Insertions would be in O(n). Sep 17 '10 at 9:27
  • 2
    I would add that SortedList is actually faster with smaller lists, even in "unsorted" scenario, the threshold appearing around ~700 elements in my own tests. Thus, a rule of thumb would be "use SortedList unless you need to store more than 1000 elements".
    – gatopeich
    Feb 16 '12 at 14:31
  • @gatopeich: are you talking about the speed of retrieval or of insertion? I'd expect the threshold to be more like 10 to 30 elements rather rather than 700 in the insertion scenario. In any case, adding (or removing) random items to SortedList gets extremely slow for large lists, so even if there's only a 1% chance of encountering a list of 10,000 elements, you should use SortedDictionary instead.
    – Qwertie
    Feb 26 '16 at 7:49

I don't know why MSDN says that SortedList<TKey, TValue> use a binary tree for its implementation because if you look at code with a decompiler like Reflector you realize its not true.

SortedList<TKey, TValue> is simply an array that grows over the time.

Every time you insert an element, it first check if the array has enough capacity, if not, a bigger array is recreated and old elements are copied into it (like List<T>)

After that, it searches where to insert the element, using a binary search (this is possible since the array is indexable and already sorted).

To keep the array sorted, it moves (or pushes) all the elements situated after position of element to be inserted by one position (using Array.Copy()).

Eg :

// we want to insert "3" 

4  <= 3

// we have to move some elements first

.  <= 3
5  |
8  v

That explains why performance of SortedList is so bad when you insert unsorted elements. It has to re-copy some elements almost every insertion. The only case it has not to be done is when the element has to be inserted at the end of the array.

SortedDictionary<TKey, TValue> is different and use a binary tree to insert and retrieve elements. It also has some cost at insert because sometimes the tree need to be re-balanced (but not every insertion).

Performance is quite similar while searching an element with SortedList or SortedDictionary because they both use a binary search.

In my opinion, you should never use SortedList to just sort an array. Unless you have very few elements, it will always be faster to insert values into a list (or array) and then call Sort() method.

SortedList is mostly useful when you have a list of values already sorted (eg: from database), you want to keep it sorted and perform some operations that would take advantage it is sorted (eg: Contains() method of SortedList performs a binary search instead of linear search)

SortedDictionary offers same advantages than SortedList but performs better if values to insert are not already sorted.

EDIT : If you are using .NET Framework 4.5, an alternative to SortedDictionary<TKey, TValue> is SortedSet<T>. It works the same way as SortedDictionary, using a binary tree, but keys and values are the same here.

  • 1
    The newest version of the SortedList<,> doc says: The SortedList<TKey, TValue> generic class is an array of key/value pairs – It also emphasizes that with SortedList<,> you can do things like string v = mySortedList.Values[3];, i.e. index by integer like an array. Jun 9 '13 at 15:20
  • 4
    Well if you read any basic algorithms book you would realize that one of the ways of implementing a binary tree is using an array webdocs.cs.ualberta.ca/~holte/T26/tree-as-array.html
    – Aidin
    Jan 18 '14 at 21:47
  • 1
    I would guess What tigrou means is SortedList is an array implementation whereas SortedDictionary is a Linked implementation, which would explain what he sees in the reverse engineered code and what Ash sees in his test
    – IDK
    Mar 15 '14 at 15:04

Are they meant for two different purposes?

There is not much semantic difference these two collection types in .NET make. They both offer keyed lookup as well as keep the entries in sort order of keys. In most cases you will be ok with either of them. Perhaps the only differentiator would be the indexed retrieval SortedList permits.

But performance?

However there is a performance difference which might be a stronger factor to choose between them. Here is a tabular view of their asymptotic complexity.

| Collection       | Indexed | Keyed    | Value  | Addition |  Removal | Memory  |
|                  | lookup  | lookup   | lookup |          |          |         |
| SortedList       | O(1)    | O(log n) | O(n)   | O(n)*    | O(n)     | Lesser  |
| SortedDictionary | n/a     | O(log n) | O(n)   | O(log n) | O(log n) | Greater |

* Insertion is O(1) for data that are already in sort order, so that each 
  element is added to the end of the list (assuming no resize is required).


To roughly summarize, you want a SortedList<K, V> when:

  1. you require indexed look-up.
  2. it's desirable to have lesser memory overhead.
  3. your input data is already sorted (say you get it already ordered from db).

You would instead want to prefer a SortedDictionary<K, V> when:

  1. relative overall performance matters (with respect to scaling).
  2. your input data is unordered.

Writing code

Both SortedList<K, V> and SortedDictionary<K, V> implement IDictionary<K, V>, so in your code you can return IDictionary<K, V> from the method or declare variable as IDictionary<K, V>. Basically hide the implementation detail, and code against interface.

IDictionary<K, V> x = new SortedDictionary<K, V>(); //for eg. 

In future, its easier to switch from either in case you're not happy with performance characteristic of one collection.

For more info on the two collection types see the original question linked.


Visual representation of performance differences.

enter image description here

  • 3
    How is this visual?
    – JSF
    Apr 16 '17 at 17:17
  • 1
    I had to use my eyes to see it :)
    – Markus
    Jun 22 '21 at 12:57

That's all there is to it. Retrieval of keys is comparable, but addition is much faster with Dictionaries.

I try to use SortedList as much as possible because it allows me to iterate over the keys and value collections. This is not possible with SortedDictionary as far as I know.

I'm not sure about this, but as far as I know Dictionaries store data in Tree structures, whereas List store data in linear arrays. That explains why insertion and removal is much faster with dictionaries, since less memory has to be shifted around. It also explains why you can iterate over SortedLists but not SortedDictionary.

  • 5
    SortedDictionary has Keys and Values collections to iterate over. The only thing it lacks is indexed access to the elements of these two collections, which the SortedList does allow.
    – jerryjvl
    Sep 4 '09 at 3:00
  • Sorry, yes. You can foreach them, but I almost never use foreach loops, which is why I mistakingly thought it wasn't possible at all. Sep 4 '09 at 3:30
  • 1
    "I'm not sure about this, but as far as I know Dictionaries store data in Tree structures" this is incorrect. The standard dictionary class in .net uses an array.
    – AaronHS
    Mar 22 '14 at 11:18

An important consideration for us is the fact that we often have small dictionaries (<100 elements), and current processessors much faster at accessing sequential memory while performing few difficult to predict branches. (i.e. iterating over a linear array rather than traversing a tree) So when you have less than about 60 elements in your dictionary, SortedList<> is often the fastest and most memory efficient dictionary in many use cases.

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