Given that indexing is so important as your data set increases in size, can someone explain how does indexing work at a database-agnostic level?
For information on queries to index a field, check out How do I index a database column.
For information on queries to index a field, check out How do I index a database column.
Answers
Why is it needed?
When data is stored on disk-based storage devices, it is stored as blocks of data. These blocks are accessed in their entirety, making them the atomic disk access operation. Disk blocks are structured in much the same way as linked lists; both contain a section for data, a pointer to the location of the next node (or block), and both need not be stored contiguously.
Due to the fact that a number of records can only be sorted on one field, we can state that searching on a field that isn’t sorted requires a Linear Search which requires
N/2
block accesses (on average), where N
is the number of blocks that the table spans. If that field is a non-key field (i.e. doesn’t contain unique entries) then the entire tablespace must be searched at N
block accesses.
Whereas with a sorted field, a Binary Search may be used, which has
log2 N
block accesses. Also since the data is sorted given a non-key field, the rest of the table doesn’t need to be searched for duplicate values, once a higher value is found. Thus the performance increase is substantial.
What is indexing?
Indexing is a way of sorting a number of records on multiple fields. Creating an index on a field in a table creates another data structure which holds the field value, and a pointer to the record it relates to. This index structure is then sorted, allowing Binary Searches to be performed on it.
The downside to indexing is that these indexes require additional space on the disk since the indexes are stored together in a table using the MyISAM engine, this file can quickly reach the size limits of the underlying file system if many fields within the same table are indexed.
How does it work?
Firstly, let’s outline a sample database table schema;
Field name Data type Size on disk id (Primary key) Unsigned INT 4 bytes firstName Char(50) 50 bytes lastName Char(50) 50 bytes emailAddress Char(100) 100 bytes
Note: char was used in place of varchar to allow for an accurate size on disk value. This sample database contains five million rows and is unindexed. The performance of several queries will now be analyzed. These are a query using the id (a sorted key field) and one using the firstName (a non-key unsorted field).
Example 1 - sorted vs unsorted fields
Given our sample database of
r = 5,000,000
records of a fixed size giving a record length of R = 204
bytes and they are stored in a table using the MyISAM engine which is using the default block size B = 1,024
bytes. The blocking factor of the table would be bfr = (B/R) = 1024/204 = 5
records per disk block. The total number of blocks required to hold the table is N = (r/bfr) = 5000000/5 = 1,000,000
blocks.
A linear search on the id field would require an average of
N/2 = 500,000
block accesses to find a value, given that the id field is a key field. But since the id field is also sorted, a binary search can be conducted requiring an average of log2 1000000 = 19.93 = 20
block accesses. Instantly we can see this is a drastic improvement.
Now the firstName field is neither sorted nor a key field, so a binary search is impossible, nor are the values unique, and thus the table will require searching to the end for an exact
N = 1,000,000
block accesses. It is this situation that indexing aims to correct.
Given that an index record contains only the indexed field and a pointer to the original record, it stands to reason that it will be smaller than the multi-field record that it points to. So the index itself requires fewer disk blocks than the original table, which therefore requires fewer block accesses to iterate through. The schema for an index on the firstName field is outlined below;
Field name Data type Size on disk firstName Char(50) 50 bytes (record pointer) Special 4 bytes
Note: Pointers in MySQL are 2, 3, 4 or 5 bytes in length depending on the size of the table.
Example 2 - indexing
Given our sample database of
r = 5,000,000
records with an index record length of R = 54
bytes and using the default block size B = 1,024
bytes. The blocking factor of the index would be bfr = (B/R) = 1024/54 = 18
records per disk block. The total number of blocks required to hold the index is N = (r/bfr) = 5000000/18 = 277,778
blocks.
Now a search using the firstName field can utilize the index to increase performance. This allows for a binary search of the index with an average of
log2 277778 = 18.08 = 19
block accesses. To find the address of the actual record, which requires a further block access to read, bringing the total to 19 + 1 = 20
block accesses, a far cry from the 1,000,000 block accesses required to find a firstName match in the non-indexed table.
When should it be used?
Given that creating an index requires additional disk space (277,778 blocks extra from the above example, a ~28% increase), and that too many indexes can cause issues arising from the file systems size limits, careful thought must be used to select the correct fields to index.
Since indexes are only used to speed up the searching for a matching field within the records, it stands to reason that indexing fields used only for output would be simply a waste of disk space and processing time when doing an insert or delete operation, and thus should be avoided. Also given the nature of a binary search, the cardinality or uniqueness of the data is important. Indexing on a field with a cardinality of 2 would split the data in half, whereas a cardinality of 1,000 would return approximately 1,000 records. With such a low cardinality the effectiveness is reduced to a linear sort, and the query optimizer will avoid using the index if the cardinality is less than 30% of the record number, effectively making the index a waste of space.
An index is just a data structure that makes the searching faster for a specific column in a database. This structure is usually a b-tree or a hash table but it can be any other logic structure.
Classic example "Index in Books"
Consider a "Book" of 1000 pages, divided by 100 sections, each section with X pages.
Simple, huh?
Now, without an index page, to find a particular section that starts with letter "S", you have no other option than scanning through the entire book. i.e: 1000 pages
But with an index page at the beginning, you are there. And more, to read any particular section that matters, you just need to look over the index page, again and again, every time. After finding the matching index you can efficiently jump to the section by skipping other sections.
But then, in addition to 1000 pages, you will need another ~10 pages to display the index page, so totally 1010 pages.
Thus, the index is a separate section that stores values of indexed column + pointer to the indexed row in a sorted order for efficient look-ups.
Things are simple in schools, isn't it? :P
Just a quick suggestion.. As indexing costs you additional writes and storage space, so if your application requires more insert/update operation, you might want to use tables without indexes, but if it requires more data retrieval operations, you should go for indexed table.
SQL index is something related to speedup the search in SQL Database. Index allows programmer to retrieve data from database very fast. Suppose you are a student or some book reader. Your book contains 50,000 pages. First day you read some topic “ABC” next day you want to read some another topic “xyz”. you will never manually go through page by page. What you will do in this situation is to use Book index to look the some specific topic and then Jump directly to your topic. Index saved your lots of time to search topic. Same in SQL index, Index allows to search millions of records very quickly from database.
0 comments:
Post a Comment