The Anatomy of an Index
An index is a distinct data structure within a database and is data redundancy. Its primary purpose is to provide an ordered representation of the indexed data through a logical ordering which is independent of the physical ordering. We do this using a doubly linked list and a tree structure known as the balanced search tree (B-tree). B-trees are nice because they keep data sorted and allow searches, access, insertions, and deletions in logarithmic time. Because of the doubly linked list, we are able to go backwards or forwards as needed on the index for various queries easily. Inserts become simple since we only have to rearrange pointers to the different pieces of data. Databases use these doubly linked list to connect leaf nodes (usually in a B+ tree or B-tree), each of which are stored in a page, and to establish logical ordering between the leaf nodes. Operations like
INSERT become slower because they are actually two writing operations in the filesystem (one for the table data and one for the index data).
Defining an Optimal Index With WHERE
To define an optimal index you must not only understand how indexes work, but you must also understand how the application queries the data. E.g., you must know the column combinations that appear in the
A common restriction with queries on
FIRST_NAME columns deals with case sensitivity. For example, instead of doing an exact search like
Hotinger we would prefer to match all results such as
HoTingEr and so on. This is very easy to do in a
WHERE clause: we just say
WHERE UPPER(LAST_NAME) = UPPER('Hotinger')
However, if we define an index of
LAST_NAME and query, it will actually run a full table scan because the query is not on
LAST_NAME but on
UPPER(LAST_NAME). From the database's perspective, this is completely different. So, in this case you should define the index on
Indexes do not necessarily have to be for one column. For example, if the primary key is a composite key (consisting of multiple columns) it will create a concatenated index also known as a combined index. Note that the ordering of the concatenated index has a significant impact on its usability and scalability so it must be chosen carefully. Basically, the ordering should match the way it is ordered in the
Defining an Optimal Index With LIKE
The position of the wildcard characters makes a huge difference.
LIKE clauses only use the characters before the wildcard during tree traversal; the rest do not narrow the scanned index range. The more selective the prefix of the
LIKE clause the more narrow the scanned index becomes. This makes the index lookup faster. As a tip, avoid
LIKE clauses which lead with wildcards like
"%OTINGER%" For full-text searches, MySQL offers
AGAINST keywords. Starting with MySQL 5.6, you can have full-text indexes. Look at Full-Text Search Functions from MySQL for more in-depth discussion on indexing these results.