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I am really interested on how MySQL indexes work that it could not scan the whole table to give us results? It's off-topic, I know, but if there is someone who could explain me that picturesquely I would be very very thankful.

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2  
    
This is a very broad question. If you have a specific example of a query that won't use an index, and you don't know why, you could post it and people might help. –  Hammerite Aug 25 '10 at 16:16
    
SELECT * FROM members WHERE id = '1' - so why with index it works faster? What that index does here? –  good_evening Aug 25 '10 at 16:17
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That looks like a query that just looks up a specific, indexed record (perhaps identified by primary key). The index makes this faster because it is stored in memory, the corresponding index row can be looked at and it contains a pointer to where the actual data is stored. So MySQL can go to the exact location in the table without having to scan the table. –  Hammerite Aug 25 '10 at 16:21

6 Answers 6

up vote 136 down vote accepted

Basically an index on a table works like an index in a book (that's where the name came from):

Let's say you have a book about databases and you want to find some information about, say, storage. Without an index (assuming no other aid, such as a table of contents) you'd have to go through the pages one by one, until you found the topic (that's a full table scan). On the other hand, an index has a list of keywords, so you'd consult the index and see that storage is mentioned on pages 113-120,231 and 354. Then you could flip to those pages directly, without searching (that's a search with an index, somewhat faster).

Of course, how useful the index will be, depends on many things - a few examples, using the simile above:

  • if you had a book on databases and indexed the word "database", you'd see that it's mentioned on pages 1-59,61-290, and 292 to 400. In such case, the index is not much help and it might be faster to go through the pages one by one (in a database, this is "poor selectivity").
  • For a 10-page book, it makes no sense to make an index, as you may end up with a 10-page book prefixed by a 5-page index, which is just silly - just scan the 10 pages and be done with it.
  • The index also needs to be useful - there's generally no point to index e.g. the frequency of the letter "L" per page.
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The first thing you must know is that indexes are a way to avoid scanning the full table to obtain the result that you're looking for.

There are different kinds of indexes and they're implemented in the storage layer, so there's no standard between them and they also depend on the storage engine that you're using.

InnoDB and the B+Tree index

For InnoDB, the most common index type is the B+Tree based index, that stores the elements in a sorted order. Also, you don't have to access the real table to get the indexed values, which makes your query return way faster.

The "problem" about this index type is that you have to query for the leftmost value to use the index. So, if your index has two columns, say last_name and first_name, the order that you query these fields matters a lot.

So, given the following table:

CREATE TABLE person (
    last_name VARCHAR(50) NOT NULL,
    first_name VARCHAR(50) NOT NULL,
    INDEX (last_name, first_name)
);

This query would take advantage of the index:

SELECT last_name, first_name FROM person
WHERE last_name = "John" AND first_name LIKE "J%"

But the following one would not

SELECT last_name, first_name FROM person WHERE first_name = "Constantine"

Because you're querying the first_name column first and it's not the leftmost column in the index.

This last example is even worse:

SELECT last_name, first_name FROM person WHERE first_name LIKE "%Constantine"

Because now, you're comparing the rightmost part of the rightmost field in the index.

The hash index

This is a different index type that unfortunately, only the memory backend supports. It's lightning fast but only useful for full lookups, which means that you can't use it for operations like >, < or LIKE.

Since it only works for the memory backend, you probably won't use it very often. The main case I can think of right now is the one that you create a temporary table in the memory with a set of results from another select and perform a lot of other selects in this temporary table using hash indexes.

If you have a big VARCHAR field, you can "emulate" the use of a hash index when using a B-Tree, by creating another column and saving a hash of the big value on it. Let's say you're storing a url in a field and the values are quite big. You could also create an integer field called url_hash and use a hash function like CRC32 or any other hash function to hash the url when inserting it. And then, when you need to query for this value, you can do something like this:

SELECT url FROM url_table WHERE url_hash=CRC32("http://gnu.org");

The problem with the above example is that since the CRC32 function generates a quite small hash, you'll end up with a lot of collisions in the hashed values. If you need exact values, you can fix this problem by doing the following:

SELECT url FROM url_table 
WHERE url_hash=CRC32("http://gnu.org") AND url="http://gnu.org";

It's still worth to hash things even if the collision number is high cause you'll only perform the second comparison (the string one) against the repeated hashes.

Unfortunately, using this technique, you still need to hit the table to compare the url field.

Wrap up

Some facts that you may consider every time you want to talk about optimization:

  1. Integer comparison is way faster than string comparison. It can be illustrated with the example about the emulation of the hash index in InnoDB.

  2. Maybe, adding additional steps in a process makes it faster, not slower. It can be illustrated by the fact that you can optimize a SELECT by splitting it into two steps, making the first one store values in a newly created in-memory table, and then execute the heavier queries on this second table.

MySQL has other indexes too, but I think the B+Tree one is the most used ever and the hash one is a good thing to know, but you can find the other ones in the MySQL documentation.

I highly recommend you to read the "High Performance MySQL" book, the answer above was definitely based its chapter about indexes.

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Will following queries have advantage in above case?1.SELECT last_name, first_name FROM person WHERE last_name= "Constantine" 2. SELECT last_name, first_name FROM person WHERE last_name LIKE "%Constantine" –  Akshay Taru Nov 30 '13 at 6:18
    
First querry will, second query will not. Use EXPLAIN: dev.mysql.com/doc/refman/5.5/en/explain.html For indexing second query with MySQL, you have to use FULLTEXT INDEX: dev.mysql.com/doc/refman/5.5/en/fulltext-search.html –  Emilio Nicolás May 29 '14 at 11:30

Basically an index is a map of all your keys that is sorted in order. With a list in order, then instead of checking every key, it can do something like this:

1: Go to middle of list - is higher or lower than what I'm looking for?

2: If higher, go to halfway point between middle and bottom, if lower, middle and top

3: Is higher or lower? Jump to middle point again, etc.

Using that logic, you can find an element in a sorted list in about 7 steps, instead of checking every item.

Obviously there are complexities, but that gives you the basic idea.

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This is called binary search. –  ddlshack Jun 11 '12 at 16:09
    
Thanks, finally a answer that explains why it is quicker and not just how the db functions with indexes. –  Gershon Herczeg Jul 9 '13 at 16:27
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Why it's 7 steps? –  Philip007 Jul 22 '13 at 6:44
    
The actual number of steps is highly dependent on the data - number of unique value and distribution across your range. 7 is the theoretical max for 100 values. Full discussion of how to calculate the number of steps here stackoverflow.com/questions/10571170/… –  Joshua May 14 at 15:44

What is an index?

So, what is an index? Well, an index is a data structure (most commonly a B- tree) that stores the values for a specific column in a table. An index is created on a column of a table. So, the key points to remember are that an index consists of column values from one table, and that those values are stored in a data structure. The index is a data structure – remember that.

Let’s start out our tutorial and explanation of why you would need a database index by going through a very simple example. Suppose that we have a database table called Employee with three columns – Employee_Name, Employee_Age, and Employee_Address. Assume that the Employee table has thousands of rows.

Now, let’s say that we want to run a query to find all the details of any employees who are named ‘Jesus’? So, we decide to run a simple query like this:

SELECT * FROM Employee 
WHERE Employee_Name = 'Jesus'

What would happen without an index on the table?

Once we run that query, what exactly goes on behind the scenes to find employees who are named Jesus? Well, the database software would literally have to look at every single row in the Employee table to see if the Employee_Name for that row is ‘Jesus’. And, because we want every row with the name ‘Jesus’ inside it, we can not just stop looking once we find just one row with the name ‘Jesus’, because there could be other rows with the name Jesus. So, every row up until the last row must be searched` – which means thousands of rows in this scenario will have to be examined by the database to find the rows with the name ‘Jesus’. This is what is called a full table scan.

How a database index can help performance

You might be thinking that doing a full table scan sounds inefficient for something so simple – shouldn’t software be smarter? It’s almost like looking through the entire table with the human eye – very slow and not at all sleek. But, as you probably guessed by the title of this article, this is where indexes can help a great deal. The whole point of having an index is to speed up search queries by essentially cutting down the number of records/rows in a table that need to be examined.


What kind of data structure is an index?

B- trees are the most commonly used data structures for indexes. The reason B- trees are the most popular data structure for indexes is due to the fact that they are time efficient – because look-ups, deletions, and insertions can all be done in logarithmic time. And, another major reason B- trees are more commonly used is because the data that is stored inside the B- tree can be sorted. The RDBMS typically determines which data structure is actually used for an index. But, in some scenarios with certain RDBMS’s, you can actually specify which data structure you want your database to use when you create the index itself.

How does an index improve performance?

Because an index is basically a data structure that is used to store column values, looking up those values becomes much faster. And, if an index is using the most commonly used data structure type – a B- tree – then the data structure is also sorted. Having the column values be sorted can be a major performance enhancement – read on to find out why. Let’s say that we create a B- tree index on the Employee_Name column This means that when we search for employees named “Jesus” using the SQL we showed earlier, then the entire Employee table does not have to be searched to find employees named “Jesus”. Instead, the database will use the index to find employees named Jesus, because the index will presumably be sorted alphabetically by the Employee’s name. And, because it is sorted, it means searching for a name is a lot faster because all names starting with a “J” will be right next to each other in the index! It’s also important to note that the index also stores pointers to the table row so that other column values can be retrieved – read on for more details on that.

How to create an index in SQL:

Here’s what the actual SQL would look like to create an index on the Employee_Name column from our example earlier:

CREATE INDEX name_index
ON Employee (Employee_Name)

How to create a multi-column index in SQL:

We could also create an index on two of the columns in the Employee table , as shown in this SQL:

CREATE INDEX name_index
ON Employee (Employee_Name, Employee_Age)
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Take a look at this link: http://dev.mysql.com/doc/refman/5.0/en/mysql-indexes.html

How they work is too broad of a subject to cover in one SO post.

Here is one of the best explanations of indexes I have seen. Unfortunately it is for SQL Server and not MySQL. I'm not sure how similar the two are...

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Nice article. I don't know SQL Server, but the basic workings look very similar. (metanote: disabling CSS styles in the 2nd linked article unhides the content) –  Piskvor Aug 25 '10 at 16:24

Database index, or just index, helps speed up the retrieval of data from tables. When you query data from a table, first MySQL checks if the indexes exist, then MySQL uses the indexes to select exact physical corresponding rows of the table instead of scanning the whole table.

A database index is similar to an index of a book. If you want to find a topic, you look up in the index first, and then you open the page that has the topic without scanning the whole book.

It is highly recommended that you should create index on columns of table from which you often query the data. Notice that all primary key columns are in the primary index of the table automatically.

If index helps speed up the querying data, why don’t we use indexes for all columns? If you create an index for every column, MySQL has to build and maintain the index table. Whenever a change is made to the records of the table, MySQL has to rebuild the index, which takes time as well as decreases the performance of the database server. Creating MySQL Index

You often create indexes when you create tables. MySQL automatically add any column that is declared as PRIMARY KEY, KEY, UNIQUE or INDEX to the index. In addition, you can add indexes to the tables that already have data.

In order to create indexes, you use the CREATE INDEX statement. The following illustrates the syntax of the CREATE INDEX statement: 1 2 3

CREATE [UNIQUE|FULLTEXT|SPATIAL] INDEX index_name USING [BTREE | HASH | RTREE] ON table_name (column_name [(length)] [ASC | DESC],...)

First, you specify the index based on the table type or storage engine:

UNIQUE means MySQL will create a constraint that all values in the index must be unique. Duplicate NULL value is allowed in all storage engine except BDB. FULLTEXT index is supported only by MyISAM storage engine and only accepted on column that has data type is CHAR, VARCHAR or TEXT. SPATIAL index supports spatial column and is available on MyISAM storage engine. In addition, the column value must not be NULL.

Then, you name the index and its type after the USING keyword such as BTREE, HASH or RTREE also based on the storage engine of the table.

Here are the storage engines of the table with the corresponding allowed index types: Storage Engine Allowable Index Types MyISAM BTREE, RTREE InnoDB BTREE MEMORY/HEAP HASH, BTREE NDB HASH

Third, you declare table name and a list columns that you want to add to the index. Example of creating index in MySQL

In the sample database, you can add officeCode column of the employees table to the index by using the CREATE INDEX statement as follows: 1

CREATE INDEX officeCode ON employees(officeCode)

Removing Indexes

Besides creating index, you can also remove index by using the DROP INDEX statement. Interestingly, the DROP INDEX statement is also mapped to ALTER TABLE statement. The following is the syntax of removing the index: 1

DROP INDEX index_name ON table_name

For example, if you want to drop index officeCode of the employees table, which we have created above, you can execute following query: 1

DROP INDEX officeCode ON employees

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