If you continue this experiment, you'll observe some behavior which is specific to the
Dictionary<TKey, TValue> implementation, and some behavior that is required due to the way you implemented
First, it's important to understand the role of
Equals when comparing objects for equality. Additional information is available on this question, but I'll repeat the basic rules here:
Equals method establishes exactly which objects are equal and which objects are not. All necessary checks need to be performed in this method for a final determination before returning.
- A hash code is a value calculated from the value of your object. Typically it is much smaller than the original object (in our case the hash code is a 4 byte integer) and not necessarily unique. However it is much faster to compute and compare to each other than the original objects themselves.
- When hash codes do not need to be unique, different hash codes indicate different objects (i.e.
Equals will definitely return false), but equal hash codes do not mean anything (i.e.
Equals could return true or false).
Collections which associate values with a key object (e.g.
IDictionary<TKey, TValue> in .NET, or
Map<K, V> in Java) take advantage of the hash codes to improve implementation efficiency. However, since the documentation for
Object.GetHashCode specifically does not require the results to be unique, these collections cannot rely on the hash codes alone for proper functionality. When two objects have the same hash code, only a call to
Equals can distinguish them. The case you describe for the insertion of
emp3 falls into this case: the [
IDictionary<TKey, TValue>.Add] method needs to throw an
ArgumentException if you are trying to insert the same value, and only a call to
Equals can determine if the new key
emp3 is equal to the previously inserted
Additional implementation characteristics
The particular collection implementation may result in more calls to
GetHashCode than you anticipate. For example, when the internal storage of a hash table is resized, an implementation might call
GetHashCode for every object stored in the collection. Collections based on a binary- or B-tree might only call
GetHashCode once (if the results are cached in the tree structure), or might need to call
GetHashCode for multiple objects during every insertion or lookup operation (if the results are not cached).
Sometimes hash table implementations need to call
GetHashCode for multiple objects, or perhaps even
Equals for objects with different hash codes due to the way they use modulo arithmetic to place keys into "buckets". The specific characteristics of this vary from one implementation to the next.