SQL ( /ˈɛs kjuː ˈɛl/ "S-Q-L";^[3] sometimes referred to as Structured Query Language) is a special-purpose programming language designed for managing data in relational database management systems (RDBMS).

Originally based upon relational algebra and tuple relational calculus,^[4] its scope includes data insert, query, update and delete, schema creation and modification, and data access control.

SQL was one of the first commercial languages for Edgar F. Codd's relational model, as described in his influential 1970 paper, "A Relational Model of Data for Large Shared Data Banks".^[5] Despite not adhering to the relational model as described by Codd, it became the most widely used database language.^[6][7] Although SQL is often described as, and to a great extent is, a declarative language, it also includes procedural elements. SQL became a standard of the American National Standards Institute (ANSI) in 1986, and of the International Organization for Standards (ISO) in 1987. Since then, the standard has been enhanced several times with added features. However, issues of SQL code portability between major RDBMS products still exist due to lack of full compliance with, or different interpretations of, the standard. Among the reasons mentioned are the large size and incomplete specification of the standard, as well as vendor lock-in.

History[link]

SQL was initially developed at IBM by Donald D. Chamberlin and Raymond F. Boyce in the early 1970s. This version, initially called SEQUEL (Structured English Query Language), was designed to manipulate and retrieve data stored in IBM's original quasi-relational database management system, System R, which a group at IBM San Jose Research Laboratory had developed during the 1970s.^[8] The acronym SEQUEL was later changed to SQL because "SEQUEL" was a trademark of the UK-based Hawker Siddeley aircraft company.^[9]

The first Relational Database Management System (RDBMS) was RDMS, developed at MIT in the early 1970s, soon followed by Ingres, developed in 1974 at U.C. Berkeley. Ingres implemented a query language known as QUEL, which was later supplanted in the marketplace by SQL.^[9]

In the late 1970s, Relational Software, Inc. (now Oracle Corporation) saw the potential of the concepts described by Codd, Chamberlin, and Boyce and developed their own SQL-based RDBMS with aspirations of selling it to the U.S. Navy, Central Intelligence Agency, and other U.S. government agencies. In June 1979, Relational Software, Inc. introduced the first commercially available implementation of SQL, Oracle V2 (Version2) for VAX computers. Oracle V2 beat IBM's August release of the System/38 RDBMS to market by a few weeks.^{[citation needed]}

After testing SQL at customer test sites to determine the usefulness and practicality of the system, IBM began developing commercial products based on their System R prototype including System/38, SQL/DS, and DB2, which were commercially available in 1979, 1981, and 1983, respectively.^[10]

This chart shows several of the SQL language elements that compose a single statement.

The SQL language is subdivided into several language elements, including:

• Clauses, which are constituent components of statements and queries. (In some cases, these are optional.)^[11]
• Expressions, which can produce either scalar values or tables consisting of columns and rows of data.
• Predicates, which specify conditions that can be evaluated to SQL three-valued logic (3VL) or Boolean (true/false/unknown) truth values and which are used to limit the effects of statements and queries, or to change program flow.
• Queries, which retrieve the data based on specific criteria. This is the most important element of SQL.
• Statements, which may have a persistent effect on schemata and data, or which may control transactions, program flow, connections, sessions, or diagnostics.
  • SQL statements also include the semicolon (";") statement terminator. Though not required on every platform, it is defined as a standard part of the SQL grammar.
• Insignificant whitespace is generally ignored in SQL statements and queries, making it easier to format SQL code for readability.

Queries[link]

The most common operation in SQL is the query, which is performed with the declarative SELECT statement. SELECT retrieves data from one or more tables, or expressions. Standard SELECT statements have no persistent effects on the database. Some non-standard implementations of SELECT can have persistent effects, such as the SELECT INTO syntax that exists in some databases.^[12]

Queries allow the user to describe desired data, leaving the database management system (DBMS) responsible for planning, optimizing, and performing the physical operations necessary to produce that result as it chooses.

A query includes a list of columns to be included in the final result immediately following the SELECT keyword. An asterisk ("*") can also be used to specify that the query should return all columns of the queried tables. SELECT is the most complex statement in SQL, with optional keywords and clauses that include:

• The FROM clause which indicates the table(s) from which data is to be retrieved. The FROM clause can include optional JOIN subclauses to specify the rules for joining tables.
• The WHERE clause includes a comparison predicate, which restricts the rows returned by the query. The WHERE clause eliminates all rows from the result set for which the comparison predicate does not evaluate to True.
• The GROUP BY clause is used to project rows having common values into a smaller set of rows. GROUP BY is often used in conjunction with SQL aggregation functions or to eliminate duplicate rows from a result set. The WHERE clause is applied before the GROUP BY clause.
• The HAVING clause includes a predicate used to filter rows resulting from the GROUP BY clause. Because it acts on the results of the GROUP BY clause, aggregation functions can be used in the HAVING clause predicate.
• The ORDER BY clause identifies which columns are used to sort the resulting data, and in which direction they should be sorted (options are ascending or descending). Without an ORDER BY clause, the order of rows returned by an SQL query is undefined.

The following is an example of a SELECT query that returns a list of expensive books. The query retrieves all rows from the Book table in which the price column contains a value greater than 100.00. The result is sorted in ascending order by title. The asterisk (*) in the select list indicates that all columns of the Book table should be included in the result set. <syntaxhighlight lang="sql"> SELECT *

   FROM Book
   WHERE price > 100.00
   ORDER BY title;

</syntaxhighlight>

The example below demonstrates a query of multiple tables, grouping, and aggregation, by returning a list of books and the number of authors associated with each book.

<syntaxhighlight lang="sql"> SELECT Book.title,

       count(*) AS Authors
   FROM  Book JOIN Book_author
      ON Book.isbn = Book_author.isbn
   GROUP BY Book.title;

</syntaxhighlight>

Example output might resemble the following:

Title                   Authors
----------------------  -------
SQL Examples and Guide     4
The Joy of SQL             1
An Introduction to SQL     2
Pitfalls of SQL            1

Under the precondition that isbn is the only common column name of the two tables and that a column named title only exists in the Books table, the above query could be rewritten in the following form:

<syntaxhighlight lang="sql"> SELECT title,

       count(*) AS Authors
   FROM  Book NATURAL JOIN Book_author
   GROUP BY title;

</syntaxhighlight>

However, many vendors either do not support this approach, or require certain column naming conventions in order for natural joins to work effectively.

SQL includes operators and functions for calculating values on stored values. SQL allows the use of expressions in the select list to project data, as in the following example which returns a list of books that cost more than 100.00 with an additional sales_tax column containing a sales tax figure calculated at 6% of the price.

<syntaxhighlight lang="sql"> SELECT isbn,

       title,
       price,
       price * 0.06 AS sales_tax
   FROM Book
   WHERE price > 100.00
   ORDER BY title;

</syntaxhighlight>

Subqueries[link]

Queries can be nested so that the results of one query can be used in another query via a relational operator or aggregation function. A nested query is also known as a subquery. While joins and other table operations provide computationally superior (i.e. faster) alternatives in many cases, the use of subqueries introduces a hierarchy in execution which can be useful or necessary. In the following example, the aggregation function AVG receives as input the result of a subquery: <syntaxhighlight lang="sql"> SELECT isbn, title, price

   FROM Book
   WHERE price < AVG(SELECT price FROM Book)
   ORDER BY title;

</syntaxhighlight>

Null and three-valued logic (3VL)[link]

The idea of Null was introduced into SQL to handle missing information in the relational model. The introduction of Null (or Unknown) along with True and False is the foundation of three-valued logic. Null does not have a value (and is not a member of any data domain) but is rather a placeholder or "mark" for missing information. Therefore comparisons with Null can never result in either True or False but always in the third logical result.^[13]

SQL uses Null to handle missing information. It supports three-valued logic (3VL) and the rules governing SQL three-valued logic are shown below (p and q represent logical states).^[14] The word NULL is also a reserved keyword in SQL, used to identify the Null special marker.

Additionally, since SQL operators return Unknown when comparing anything with Null, SQL provides two Null-specific comparison predicates: IS NULL and IS NOT NULL test whether data is or is not Null.^[13]

Note that SQL returns only results for which the WHERE clause returns a value of True; i.e. it excludes results with values of False and also excludes those whose value is Unknown.

Universal quantification is not explicitly supported by SQL, and must be worked out as a negated existential quantification.^[15][16][17]

There is also the "<row value expression> IS DISTINCT FROM <row value expression>" infixed comparison operator which returns TRUE unless both operands are equal or both are NULL. Likewise, IS NOT DISTINCT FROM is defined as "NOT (<row value expression> IS DISTINCT FROM <row value expression>)".

Data manipulation[link]

The Data Manipulation Language (DML) is the subset of SQL used to add, update and delete data:

• INSERT adds rows (formally tuples) to an existing table, e.g.,:

<syntaxhighlight lang="sql"> INSERT INTO My_table

       (field1, field2, field3)
   VALUES
       ('test', 'N', NULL);

</syntaxhighlight>

• UPDATE modifies a set of existing table rows, e.g.,:

<syntaxhighlight lang="sql"> UPDATE My_table

   SET field1 = 'updated value'
   WHERE field2 = 'N';

</syntaxhighlight>

• DELETE removes existing rows from a table, e.g.,:

<syntaxhighlight lang="sql"> DELETE My_table

   WHERE field2 = 'N';

</syntaxhighlight>

• MERGE is used to combine the data of multiple tables. It combines the INSERT and UPDATE elements. It is defined in the SQL:2003 standard; prior to that, some databases provided similar functionality via different syntax, sometimes called "upsert".

Transaction controls[link]

Transactions, if available, wrap DML operations:

• START TRANSACTION (or BEGIN WORK, or BEGIN TRANSACTION, depending on SQL dialect) mark the start of a database transaction, which either completes entirely or not at all.
• SAVE TRANSACTION (or SAVEPOINT ) save the state of the database at the current point in transaction

<syntaxhighlight lang="sql"> CREATE TABLE tbl_1(id int);

 INSERT INTO tbl_1(id) VALUES(1);
 INSERT INTO tbl_1(id) VALUES(2);

COMMIT;

 UPDATE tbl_1 SET id=200 WHERE id=1;

SAVEPOINT id_1upd;

 UPDATE tbl_1 SET id=1000 WHERE id=2;

ROLLBACK to id_1upd;

 SELECT id from tbl_1;

</syntaxhighlight>

• COMMIT causes all data changes in a transaction to be made permanent.
• ROLLBACK causes all data changes since the last COMMIT or ROLLBACK to be discarded, leaving the state of the data as it was prior to those changes.

Once the COMMIT statement completes, the transaction's changes cannot be rolled back.

COMMIT and ROLLBACK terminate the current transaction and release data locks. In the absence of a START TRANSACTION or similar statement, the semantics of SQL are implementation-dependent. Example: A classic bank transfer of funds transaction.

<syntaxhighlight lang="sql"> START TRANSACTION;

 UPDATE Account SET amount=amount-200 WHERE account_number=1234;
 UPDATE Account SET amount=amount+200 WHERE account_number=2345;

IF ERRORS=0 COMMIT; IF ERRORS<>0 ROLLBACK; </syntaxhighlight>

Data definition[link]

The Data Definition Language (DDL) manages table and index structure. The most basic items of DDL are the CREATE, ALTER, RENAME, DROP and TRUNCATE statements:

• CREATE creates an object (a table, for example) in the database, e.g.,:

<syntaxhighlight lang="sql"> CREATE TABLE My_table(

   my_field1   INT,
   my_field2   VARCHAR(50),
   my_field3   DATE         NOT NULL,
   PRIMARY KEY (my_field1, my_field2)

); </syntaxhighlight>

• ALTER modifies the structure of an existing object in various ways, for example, adding a column to an existing table or a constraint, e.g.,:

<syntaxhighlight lang="sql"> ALTER TABLE My_table ADD my_field4 NUMBER(3) NOT NULL; </syntaxhighlight>

• TRUNCATE deletes all data from a table in a very fast way, deleting the data inside the table and not the table itself. It usually implies a subsequent COMMIT operation, i.e., it cannot be rolled back.(data is not written to the logs for rollback later, unlike DELETE )

<syntaxhighlight lang="sql"> TRUNCATE TABLE My_table; </syntaxhighlight>

• DROP deletes an object in the database, usually irretrievably, i.e., it cannot be rolled back, e.g.,:

<syntaxhighlight lang="sql"> DROP TABLE My_table; </syntaxhighlight>

Data types[link]

Each column in an SQL table declares the type(s) that column may contain. ANSI SQL includes the following data types.^[18]

Character strings[link]

• CHARACTER(n) or CHAR(n) — fixed-width n-character string, padded with spaces as needed
• CHARACTER VARYING(n) or VARCHAR(n) — variable-width string with a maximum size of n characters
• NATIONAL CHARACTER(n) or NCHAR(n) — fixed width string supporting an international character set
• NATIONAL CHARACTER VARYING(n) or NVARCHAR(n) — variable-width NCHAR string

Bit strings[link]

• BIT(n) — an array of n bits
• BIT VARYING(n) — an array of up to n bits

Numbers[link]

• INTEGER and SMALLINT
• FLOAT, REAL and DOUBLE PRECISION
• NUMERIC(precision, scale) or DECIMAL(precision, scale)

For example, the number 123.45 has a precision of 5 and a scale of 2. The precision is a positive integer that determines the number of significant digits in a particular radix (binary or decimal). The scale is a non-negative integer. A scale of 0 indicates that the number is an integer. For a decimal number with scale S, the exact numeric value is the integer value of the significant digits divided by 10^S.

SQL provides a function to round numerics or dates, called TRUNC (in Informix, DB2, PostgreSQL, Oracle and MySQL) or ROUND (in Informix, Sybase, Oracle, PostgreSQL and Microsoft SQL Server)^[19]

Date and time[link]

• DATE — for date values (e.g., 2011-05-03)
• TIME — for time values (e.g., 15:51:36). The granularity of the time value is usually a tick (100 nanoseconds).
• TIME WITH TIME ZONE or TIMETZ — the same as TIME, but including details about the time zone in question.
• TIMESTAMP — This is a DATE and a TIME put together in one variable (e.g., 2011-05-03 15:51:36).
• TIMESTAMP WITH TIME ZONE or TIMESTAMPTZ — the same as TIMESTAMP, but including details about the time zone in question.

SQL provides several functions for generating a date / time variable out of a date / time string (TO_DATE, TO_TIME, TO_TIMESTAMP), as well as for extracting the respective members (seconds, for instance) of such variables. The current system date / time of the database server can be called by using functions like NOW.

Data control[link]

The Data Control Language (DCL) authorizes users and groups of users to access and manipulate data. Its two main statements are:

• GRANT authorizes one or more users to perform an operation or a set of operations on an object.
• REVOKE eliminates a grant, which may be the default grant.

Example: <syntaxhighlight lang="sql"> GRANT SELECT, UPDATE

   ON My_table
   TO some_user, another_user;

REVOKE SELECT, UPDATE

   ON My_table
   FROM some_user, another_user;

</syntaxhighlight>

Procedural extensions[link]

SQL is designed for a specific purpose: to query data contained in a relational database. SQL is a set-based, declarative query language, not an imperative language such as C or BASIC. However, there are extensions to Standard SQL which add procedural programming language functionality, such as control-of-flow constructs. These include:

In addition to the standard SQL/PSM extensions and proprietary SQL extensions, procedural and object-oriented programmability is available on many SQL platforms via DBMS integration with other languages. The SQL standard defines SQL/JRT extensions (SQL Routines and Types for the Java Programming Language) to support Java code in SQL databases. SQL Server 2005 uses the SQLCLR (SQL Server Common Language Runtime) to host managed .NET assemblies in the database, while prior versions of SQL Server were restricted to using unmanaged extended stored procedures which were primarily written in C. PostgreSQL allows functions to be written in a wide variety of languages including Perl, Python, Tcl, and C.^[20]

Criticism[link]

SQL deviates in several ways from its theoretical foundation, the relational model and its tuple calculus.

In that model, a table is a set of tuples, while in SQL, tables and query results are lists of rows: the same row may occur multiple times, and the order of rows can be employed in queries (e.g. in the LIMIT clause).

Furthermore, additional features (such as NULL and views) were introduced without founding them directly on the relational model, which makes them more difficult to interpret.

Critics argue that SQL should be replaced with a language that strictly returns to the original foundation - see, e.g., The Third Manifesto.

Other criticisms of SQL include:

• Implementations are incompatible between vendors. In particular date and time syntax, string concatenation, NULLs, and comparison case sensitivity vary from vendor to vendor. A particular exception is PostgreSQL, which strives for compliance.^[21]

Cross-vendor portability[link]

Popular implementations of SQL commonly omit support for basic features of Standard SQL, such as the DATE or TIME data types. The most obvious such examples, and incidentally the most popular commercial, proprietary SQL DBMSs, are Oracle (whose DATE behaves as DATETIME,^[22][23] and lacks a TIME type^[24]) and the MS SQL Server (before the 2008 version). As a result, SQL code can rarely be ported between database systems without modifications.

There are several reasons for this lack of portability between database systems:

• The complexity and size of the SQL standard means that most implementors do not support the entire standard.
• The standard does not specify database behavior in several important areas (e.g., indexes, file storage…), leaving implementations to decide how to behave.
• The SQL standard precisely specifies the syntax that a conforming database system must implement. However, the standard's specification of the semantics of language constructs is less well-defined, leading to ambiguity.
• Many database vendors have large existing customer bases; where the SQL standard conflicts with the prior behavior of the vendor's database, the vendor may be unwilling to break backward compatibility.
• Software vendors often desire to create incompatibilities with other products, as it provides a strong incentive for their existing users to remain loyal (see vendor lock-in).

Standardization[link]

SQL was adopted as a standard by the American National Standards Institute (ANSI) in 1986 as SQL-86^[25] and the International Organization for Standardization (ISO) in 1987. Nowadays the standard is subject to continuous improvement by the Joint Technical Committee ISO/IEC JTC 1, Information technology, Subcommittee SC 32, Data management and interchange which affiliate to ISO as well as IEC. He is commonly denoted conforming to the pattern: ISO/IEC 9075-n:yyyy Part n: title or ISO/IEC 9075 as a shortcut.

ISO/IEC 9075 is complemented by ISO/IEC 13249: SQL Multimedia and Application Packages which defines SQL based interfaces and packages to widely spread applications like video, audio and spatial data.

Until 1996, the National Institute of Standards and Technology (NIST) data management standards program certified SQL DBMS compliance with the SQL standard. Vendors now self-certify the compliance of their products.^[26]

The original SQL standard declared that the official pronunciation for SQL is "es queue el".^[6] Many English-speaking database professionals still use the nonstandard^[27] pronunciation /ˈsiːkwəl/ (like the word "sequel"), including Donald Chamberlin himself.^[28]

The SQL standard has gone through a number of revisions, as shown below:

Interested parties may purchase SQL standards documents from ISO, IEC or ANSI. A draft of SQL:2008 is freely available as a zip archive.^[31]

Standard structure[link]

The SQL standard is divided into nine parts.

• ISO/IEC 9075-1:2011 Part 1: Framework (SQL/Framework). It provides logical concepts.
• ISO/IEC 9075-2:2011 Part 2: Foundation (SQL/Foundation). It contains the most central elements of the language and consists of both mandatory and optional features.
• ISO/IEC 9075-3:2008 Part 3: Call-Level Interface (SQL/CLI). It defines interfacing components (structures, procedures, variable bindings) that can be used to execute SQL statements from applications written in Ada, C respectively C++, COBOL, Fortran, MUMPS, Pascal or PL/I. (For Java see part 10.) SQL/CLI is defined in such a way that SQL statements and SQL/CLI procedure calls are treated as separate from the calling application's source code. Open Database Connectivity is a well-known superset of SQL/CLI. This part of the standard consists solely of mandatory features.
• ISO/IEC 9075-4:2011 Part 4: Persistent Stored Modules (SQL/PSM) It standardizes procedural extensions for SQL, including flow of control, condition handling, statement condition signals and resignals, cursors and local variables, and assignment of expressions to variables and parameters. In addition, SQL/PSM formalizes declaration and maintenance of persistent database language routines (e.g., "stored procedures"). This part of the standard consists solely of optional features.
• ISO/IEC 9075-9:2008 Part 9: Management of External Data (SQL/MED). It provides extensions to SQL that define foreign-data wrappers and datalink types to allow SQL to manage external data. External data is data that is accessible to, but not managed by, an SQL-based DBMS. This part of the standard consists solely of optional features.
• ISO/IEC 9075-10:2008 Part 10: Object Language Bindings (SQL/OLB). It defines the syntax and semantics of SQLJ, which is SQL embedded in Java (see also part 3). The standard also describes mechanisms to ensure binary portability of SQLJ applications, and specifies various Java packages and their contained classes. This part of the standard consists solely of optional features. As opposed to SQL/OLB JDBC - which is not part of the SQL standard - defines an API.
• ISO/IEC 9075-11:2011 Part 11: Information and Definition Schemas (SQL/Schemata). It defines the Information Schema and Definition Schema, providing a common set of tools to make SQL databases and objects self-describing. These tools include the SQL object identifier, structure and integrity constraints, security and authorization specifications, features and packages of ISO/IEC 9075, support of features provided by SQL-based DBMS implementations, SQL-based DBMS implementation information and sizing items, and the values supported by the DBMS implementations.^[32] This part of the standard contains both mandatory and optional features.
• ISO/IEC 9075-13:2008 Part 13: SQL Routines and Types Using the Java Programming Language (SQL/JRT). It specifies the ability to invoke static Java methods as routines from within SQL applications ('Java-in-the-database'). It also calls for the ability to use Java classes as SQL structured user-defined types. This part of the standard consists solely of optional features.
• ISO/IEC 9075-14:2011 Part 14: XML-Related Specifications (SQL/XML). It specifies SQL-based extensions for using XML in conjunction with SQL. The XMLType data type is introduced, as well as several routines, functions, and XML-to-SQL data type mappings to support manipulation and storage of XML in an SQL database.^[29] This part of the standard consists solely of optional features.

ISO/IEC 9075 is complemented by ISO/IEC 13249 SQL Multimedia and Application Packages. This closely related but separate standard is developed by the same committee. It defines interfaces and packages which are based on SQL. The aim is an unified access to typical database applications like text, pictures, data mining or spatial data.

• ISO/IEC 13249-1:2007 Part 1: Framework
• ISO/IEC 13249-2:2003 Part 2: Full-Text
• ISO/IEC 13249-3:2011 Part 3: Spatial
• ISO/IEC 13249-5:2003 Part 5: Still image
• ISO/IEC 13249-6:2006 Part 6: Data mining
• ISO/IEC 13249-8:xxxx Part 8: Metadata registries (MDR) (work in progress)

Alternatives[link]

A distinction should be made between alternatives to relational query languages and alternatives to SQL. Below are proposed relational alternatives to SQL. See navigational database and NoSQL for alternatives to relational:

• .QL - object-oriented Datalog
• 4D Query Language (4D QL)
• Datalog
• HTSQL - URL based query method
• IBM Business System 12 (IBM BS12) - one of the first fully relational database management systems, introduced in 1982
• ISBL
• Java Persistence Query Language (JPQL) - The query language used by the Java Persistence API and Hibernate persistence library
• JoSQL^[33] - Runs SQL statements written as Strings to query collections from inside Java code.
• LINQ - Runs SQL statements written like language constructs to query collections directly from inside .Net code.
• Object Query Language
• QBE (Query By Example) created by Moshè Zloof, IBM 1977
• Quel introduced in 1974 by the U.C. Berkeley Ingres project.
• Tutorial D
• SBQL - the Stack Based Query Language (SBQL)
• UnQL - the Unstructured Query Language, a functional superset of SQL, developed by the authors of SQLite and CouchDB
• XQuery

See also[link]

	Book: SQL
Wikipedia books are collections of articles that can be downloaded or ordered in print.

• Comparison of object-relational database management systems
• Comparison of relational database management systems
• D (data language specification)
• D4 (programming language) (an implementation of D)
• Hierarchical model
• List of relational database management systems
• MUMPS
• NoSQL

Notes[link]

References[link]

External links[link]

Find more about SQL on Wikipedia's sister projects:
	Definitions and translations from Wiktionary
	Learning resources from Wikiversity
	Textbooks from Wikibooks

Wikibooks has a book on the topic of SQL dialects reference

• 1995 SQL Reunion: People, Projects, and Politics, by Paul McJones (ed.): transcript of a reunion meeting devoted to the personal history of relational databases and SQL.
• American National Standards Institute. X3H2 Records, 1978–1995 Charles Babbage Institute Collection documents the H2 committee’s development of the NDL and SQL standards.
• Oral history interview with Donald D. Chamberlin Charles Babbage Institute In this oral history Chamberlin recounts his early life, his education at Harvey Mudd College and Stanford University, and his work on relational database technology. Chamberlin was a member of the System R research team and, with Raymond F. Boyce, developed the SQL database language. Chamberlin also briefly discusses his more recent research on XML query languages.
• Comparison of Different SQL Implementations This comparison of various SQL implementations is intended to serve as a guide to those interested in porting SQL code between various RDBMS products, and includes comparisons between SQL:2008, PostgreSQL, DB2, MS SQL Server, MySQL, Oracle, and Informix.

Steven Feuerstein is an expert on the Oracle database PL/SQL language, having written ten books on PL/SQL, and one book on mySQL, all from O'Reilly Media.^[1] His signature book Oracle PL/SQL Programming, by many considered as the "bible" for PL/SQL developers,^[2] was published first in September 1993, covering 916 pages and has grown in its 5th edition, published 16 years later, to 1232 pages.

Steven has been developing software since 1980, spent five years with Oracle Corporation (1987-1992) and serves as PL/SQL evangelist for Quest Software, where he has been employed since January 2001.^[3] Since 2005 he has focused his attention on improving the testing of PL/SQL programs, first by starting the open-source framework utPLSQL for Unit Testing PL/SQL, later on through the creation of Quest Code Tester for Oracle, which automates PL/SQL code testing.^[4] Steven is an Oracle ACE Director and publishes regularly in Oracle Magazine and the ODTUG magazine.

In April 2010, Steven launched the PL/SQL Challenge (http://plsqlchallenge.com), a daily quiz on Oracle PL/SQL that quickly attracted over 1,000 daily players, making it one of the most active PL/SQL-related websites on the Internet. And in 2011, Steven added the PL/SQL Channel (http://plsqlchannel.com), which offers video-based training on the Oracle PL/SQL language.

Books[link]

• Advanced Oracle PL/SQL Programming with Packages, O'Reilly Media, October 1996, ISBN 1-56592-238-7
• with Charles Dye, John Beresniewicz.Oracle Built-in Packages, O'Reilly Media, May 1998, ISBN 1-56592-375-8
• with John Beresniewicz, Chip Dawes. Oracle PL/SQL Built-ins Pocket Reference, O'Reilly Media, October 1998, ISBN 1-56592-456-8
• Oracle PL/SQL Programming: Guide to Oracle8i Features, O'Reilly Media, October 1999, ISBN 1-56592-675-7
• with Andrew Odewahn. Oracle PL/SQL Programming: A Developer's Workbook, O'Reilly Media, May 2000, ISBN 1-56592-674-9
• with Bill Pribyl. Learning Oracle PL/SQL, O'Reilly Media, November 2001, ISBN 0-596-00180-0
• with Arup Nanda. Oracle PL/SQL for DBAs, First Edition, O'Reilly Media, October 2005, ISBN 0-596-00587-3
• with Guy Harrison. MySQL Stored Procedure Programming: Building High-Performance Web Applications in MySQL, O'Reilly Media, March 2006, ISBN 0-596-10089-2
• Oracle PL/SQL Best Practices, Second Edition, O'Reilly Media, October 2007, ISBN 0-596-51410-7
• with Bill Pribyl, Chip Dawes. Oracle PL/SQL Language Pocket Reference, Fourth Edition, O'Reilly Media, October 2007, ISBN 0-596-51404-2
• with Bill Pribyl. Oracle PL/SQL Programming, Fifth Edition, O'Reilly Media, September 2009, ISBN 0-596-51446-8

References[link]

1. ^ Feuerstein, Steven. "Steven Feuerstein's PL/SQL Obsession". http://www.ToadWorld.com/SF. Retrieved 23 January 2010. 
2. ^ Feuerstein, Steven. "Oracle PL/SQL Programming". http://www.oracleplsqlprogramming.com/index.html. Retrieved 23 January 2010. 
3. ^ "An Exclusive Interview with Steven Feuerstein". databasedesign-resource.com. http://www.databasedesign-resource.com/interview-with-steven-feuerstein.html. Retrieved 23 January 2010. 
4. ^ "Steven Feuerstein". oreilly.com. http://www.oreillynet.com/pub/au/344. Retrieved 23 January 2010.