An SQL join clause - corresponding to a join operation in relational algebra - combines columns from one or more tables in a relational database. It creates a set that can be saved as a table or used as it is. A
JOIN is a means for combining columns from one (self-join) or more tables by using values common to each. ANSI-standard SQL specifies five types of
FULL OUTER and
CROSS. As a special case, a table (base table, view, or joined table) can
JOIN to itself in a self-join.
A programmer declares a
JOIN statement to identify rows for joining. If the evaluated predicate is true, the combined row is then produced in the expected format, a row set or a temporary table.
- 1 Sample tables
- 2 Cross join
- 3 Inner join
- 4 Outer join
- 5 Self-join
- 6 Alternatives
- 7 Implementation
- 8 See also
- 9 References
- 10 External links
Relational databases are usually normalized to eliminate duplication of information such as when entity types have one-to-many relationships. For example, a Department may be associated with a number of Employees. Joining separate tables for Department and Employee effectively creates another table which combines the information from both tables.
All subsequent explanations on join types in this article make use of the following two tables. The rows in these tables serve to illustrate the effect of different types of joins and join-predicates. In the following tables the
DepartmentID column of the
Department table (which can be designated as
Department.DepartmentID) is the primary key, while
Employee.DepartmentID is a foreign key.
Note: In the Employee table above, the employee "Williams" has not been assigned to any department yet. Also, note that no employees are assigned to the "Marketing" department.
This is the SQL statement to create the aforementioned tables.
1 CREATE TABLE department 2 ( 3 DepartmentID INT Primary key, 4 DepartmentName VARCHAR(20) 5 ); 6 7 CREATE TABLE employee 8 ( 9 LastName VARCHAR(20), 10 DepartmentID INT references department(DepartmentID) 11 ); 12 13 INSERT INTO department VALUES(31, 'Sales'); 14 INSERT INTO department VALUES(33, 'Engineering'); 15 INSERT INTO department VALUES(34, 'Clerical'); 16 INSERT INTO department VALUES(35, 'Marketing'); 17 18 INSERT INTO employee VALUES('Rafferty', 31); 19 INSERT INTO employee VALUES('Jones', 33); 20 INSERT INTO employee VALUES('Heisenberg', 33); 21 INSERT INTO employee VALUES('Robinson', 34); 22 INSERT INTO employee VALUES('Smith', 34); 23 INSERT INTO employee VALUES('Williams', NULL);
Example of an explicit cross join:
SELECT * FROM employee CROSS JOIN department;
Example of an implicit cross join:
SELECT * FROM employee, department;
The cross join does not itself apply any predicate to filter rows from the joined table. The results of a cross join can be filtered by using a
WHERE clause which may then produce the equivalent of an inner join.
In the SQL:2011 standard, cross joins are part of the optional F401, "Extended joined table", package.
Normal uses are for checking the server's performance.
An inner join requires each row in the two joined tables to have matching column values, and is a commonly used join operation in applications but should not be assumed to be the best choice in all situations. Inner join creates a new result table by combining column values of two tables (A and B) based upon the join-predicate. The query compares each row of A with each row of B to find all pairs of rows which satisfy the join-predicate. When the join-predicate is satisfied by matching non-NULL values, column values for each matched pair of rows of A and B are combined into a result row.
The result of the join can be defined as the outcome of first taking the Cartesian product (or Cross join) of all rows in the tables (combining every row in table A with every row in table B) and then returning all rows which satisfy the join predicate. Actual SQL implementations normally use other approaches, such as hash joins or sort-merge joins, since computing the Cartesian product is slower and would often require a prohibitively large amount of memory to store.
SQL specifies two different syntactical ways to express joins: the "explicit join notation" and the "implicit join notation". The "implicit join notation" is no longer considered a best practice, although database systems still support it.
The "explicit join notation" uses the
JOIN keyword, optionally preceded by the
INNER keyword, to specify the table to join, and the
ON keyword to specify the predicates for the join, as in the following example:
SELECT employee.LastName, employee.DepartmentID, department.DepartmentName FROM employee INNER JOIN department ON employee.DepartmentID = department.DepartmentID
The "implicit join notation" simply lists the tables for joining, in the
FROM clause of the
SELECT statement, using commas to separate them. Thus it specifies a cross join, and the
WHERE clause may apply additional filter-predicates (which function comparably to the join-predicates in the explicit notation).
The following example is equivalent to the previous one, but this time using implicit join notation:
SELECT * FROM employee, department WHERE employee.DepartmentID = department.DepartmentID;
The queries given in the examples above will join the Employee and Department tables using the DepartmentID column of both tables. Where the DepartmentID of these tables match (i.e. the join-predicate is satisfied), the query will combine the LastName, DepartmentID and DepartmentName columns from the two tables into a result row. Where the DepartmentID does not match, no result row is generated.
Thus the result of the execution of the query above will be:
The employee "Williams" and the department "Marketing" do not appear in the query execution results. Neither of these has any matching rows in the other respective table: "Williams" has no associated department, and no employee has the department ID 35 ("Marketing"). Depending on the desired results, this behavior may be a subtle bug, which can be avoided by replacing the inner join with an outer join.
Programmers should take special care when joining tables on columns that can contain NULL values, since NULL will never match any other value (not even NULL itself), unless the join condition explicitly uses a combination predicate that first checks that the joins columns are
NOT NULL before applying the remaining predicate condition(s). The Inner join can only be safely used in a database that enforces referential integrity or where the join columns are guaranteed not to be NULL. Many transaction processing relational databases rely on Atomicity, Consistency, Isolation, Durability (ACID) data update standards to ensure data integrity, making inner joins an appropriate choice. However transaction databases usually also have desirable join columns that are allowed to be NULL. Many reporting relational database and data warehouses use high volume Extract, Transform, Load (ETL) batch updates which make referential integrity difficult or impossible to enforce, resulting in potentially NULL join columns that an SQL query author cannot modify and which cause inner joins to omit data with no indication of an error. The choice to use an inner join depends on the database design and data characteristics. A left outer join can usually be substituted for an inner join when the join columns in one table may contain NULL values.
Any data column that may be NULL (empty) should never be used as a link in an inner join, unless the intended result is to eliminate the rows with the NULL value. If NULL join columns are to be deliberately removed from the result set, an inner join can be faster than an outer join because the table join and filtering is done in a single step. Conversely, an inner join can result in disastrously slow performance or even a server crash when used in a large volume query in combination with database functions in an SQL Where clause. A function in an SQL Where clause can result in the database ignoring relatively compact table indexes. The database may read and inner join the selected columns from both tables before reducing the number of rows using the filter that depends on a calculated value, resulting in a relatively enormous amount of inefficient processing.
When a result set is produced by joining several tables, including master tables used to look up full text descriptions of numeric identifier codes (a Lookup table), a NULL value in any one of the foreign keys can result in the entire row being eliminated from the result set, with no indication of error. A complex SQL query that includes one or more inner joins and several outer joins has the same risk for NULL values in the inner join link columns.
A commitment to SQL code containing inner joins assumes NULL join columns will not be introduced by future changes, including vendor updates, design changes and bulk processing outside of the application's data validation rules such as data conversions, migrations, bulk imports and merges.
One can further classify inner joins as equi-joins, as natural joins, or as cross-joins.
An equi-join is a specific type of comparator-based join, that uses only equality comparisons in the join-predicate. Using other comparison operators (such as
<) disqualifies a join as an equi-join. The query shown above has already provided an example of an equi-join:
SELECT * FROM employee JOIN department ON employee.DepartmentID = department.DepartmentID;
We can write equi-join as below,
SELECT * FROM employee, department WHERE employee.DepartmentID = department.DepartmentID;
SELECT * FROM employee INNER JOIN department USING (DepartmentID);
USING construct is more than mere syntactic sugar, however, since the result set differs from the result set of the version with the explicit predicate. Specifically, any columns mentioned in the
USING list will appear only once, with an unqualified name, rather than once for each table in the join. In the case above, there will be a single
DepartmentID column and no
USING clause is not supported by MS SQL Server and Sybase.
The natural join is a special case of equi-join. Natural join (⋈) is a binary operator that is written as (R ⋈ S) where R and S are relations. The result of the natural join is the set of all combinations of tuples in R and S that are equal on their common attribute names. For an example consider the tables Employee and Dept and their natural join:
This can also be used to define composition of relations. For example, the composition of Employee and Dept is their join as shown above, projected on all but the common attribute DeptName. In category theory, the join is precisely the fiber product.
The natural join is arguably one of the most important operators since it is the relational counterpart of logical AND. Note that if the same variable appears in each of two predicates that are connected by AND, then that variable stands for the same thing and both appearances must always be substituted by the same value. In particular, the natural join allows the combination of relations that are associated by a foreign key. For example, in the above example a foreign key probably holds from Employee.DeptName to Dept.DeptName and then the natural join of Employee and Dept combines all employees with their departments. This works because the foreign key holds between attributes with the same name. If this is not the case such as in the foreign key from Dept.manager to Employee.Name then these columns have to be renamed before the natural join is taken. Such a join is sometimes also referred to as an equi-join.
More formally the semantics of the natural join are defined as follows:
where Fun is a predicate that is true for a relation r if and only if r is a function. It is usually required that R and S must have at least one common attribute, but if this constraint is omitted, and R and S have no common attributes, then the natural join becomes exactly the Cartesian product.
The natural join can be simulated with Codd's primitives as follows. Let c1, …, cm be the attribute names common to R and S, r1, …, rn be the attribute names unique to R and let s1, …, sk be the attributes unique to S. Furthermore, assume that the attribute names x1, …, xm are neither in R nor in S. In a first step the common attribute names in S can now be renamed:
Then we take the Cartesian product and select the tuples that are to be joined:
A natural join is a type of equi-join where the join predicate arises implicitly by comparing all columns in both tables that have the same column-names in the joined tables. The resulting joined table contains only one column for each pair of equally named columns. In the case that no columns with the same names are found, the result is a cross join.
Most experts agree that NATURAL JOINs are dangerous and therefore strongly discourage their use. The danger comes from inadvertently adding a new column, named the same as another column in the other table. An existing natural join might then "naturally" use the new column for comparisons, making comparisons/matches using different criteria (from different columns) than before. Thus an existing query could produce different results, even though the data in the tables have not been changed, but only augmented. The use of column names to automatically determine table links is not an option in large databases with hundreds or thousands of tables where it would place an unrealistic constraint on naming conventions. Real world databases are commonly designed with foreign key data that is not consistently populated (NULL values are allowed), due to business rules and context. It is common practice to modify column names of similar data in different tables and this lack of rigid consistency relegates natural joins to a theoretical concept for discussion.
The above sample query for inner joins can be expressed as a natural join in the following way:
SELECT * FROM employee NATURAL JOIN department;
As with the explicit
USING clause, only one DepartmentID column occurs in the joined table, with no qualifier:
PostgreSQL, MySQL and Oracle support natural joins; Microsoft T-SQL and IBM DB2 do not. The columns used in the join are implicit so the join code does not show which columns are expected, and a change in column names may change the results. In the SQL:2011 standard, natural joins are part of the optional F401, "Extended joined table", package.
In many database environments the column names are controlled by an outside vendor, not the query developer. A natural join assumes stability and consistency in column names which can change during vendor mandated version upgrades.
The joined table retains each row—even if no other matching row exists. Outer joins subdivide further into left outer joins, right outer joins, and full outer joins, depending on which table's rows are retained (left, right, or both).
(In this case left and right refer to the two sides of the
No implicit join-notation for outer joins exists in standard SQL.
Left outer join
The result of a left outer join (or simply left join) for tables A and B always contains all rows of the "left" table (A), even if the join-condition does not find any matching row in the "right" table (B). This means that if the
ON clause matches 0 (zero) rows in B (for a given row in A), the join will still return a row in the result (for that row)—but with NULL in each column from B. A left outer join returns all the values from an inner join plus all values in the left table that do not match to the right table, including rows with NULL (empty) values in the link column.
For example, this allows us to find an employee's department, but still shows employees that have not been assigned to a department (contrary to the inner-join example above, where unassigned employees were excluded from the result).
Example of a left outer join (the
OUTER keyword is optional), with the additional result row (compared with the inner join) italicized:
SELECT * FROM employee LEFT OUTER JOIN department ON employee.DepartmentID = department.DepartmentID;
Oracle supports the deprecated syntax:
SELECT * FROM employee, department WHERE employee.DepartmentID = department.DepartmentID(+)
SELECT * FROM employee, department WHERE employee.DepartmentID *= department.DepartmentID
IBM Informix supports the syntax:
SELECT * FROM employee, OUTER department WHERE employee.DepartmentID = department.DepartmentID
Right outer join
A right outer join (or right join) closely resembles a left outer join, except with the treatment of the tables reversed. Every row from the "right" table (B) will appear in the joined table at least once. If no matching row from the "left" table (A) exists, NULL will appear in columns from A for those rows that have no match in B.
A right outer join returns all the values from the right table and matched values from the left table (NULL in the case of no matching join predicate). For example, this allows us to find each employee and his or her department, but still show departments that have no employees.
Below is an example of a right outer join (the
OUTER keyword is optional), with the additional result row italicized:
SELECT * FROM employee RIGHT OUTER JOIN department ON employee.DepartmentID = department.DepartmentID;
Right and left outer joins are functionally equivalent. Neither provides any functionality that the other does not, so right and left outer joins may replace each other as long as the table order is switched.
Full outer join
Conceptually, a full outer join combines the effect of applying both left and right outer joins. Where rows in the FULL OUTER JOINed tables do not match, the result set will have NULL values for every column of the table that lacks a matching row. For those rows that do match, a single row will be produced in the result set (containing columns populated from both tables).
For example, this allows us to see each employee who is in a department and each department that has an employee, but also see each employee who is not part of a department and each department which doesn't have an employee.
Example of a full outer join (the
OUTER keyword is optional):
SELECT * FROM employee FULL OUTER JOIN department ON employee.DepartmentID = department.DepartmentID;
Some database systems do not support the full outer join functionality directly, but they can emulate it through the use of an inner join and UNION ALL selects of the "single table rows" from left and right tables respectively. The same example can appear as follows:
SELECT employee.LastName, employee.DepartmentID, department.DepartmentName, department.DepartmentID FROM employee INNER JOIN department ON employee.DepartmentID = department.DepartmentID UNION ALL SELECT employee.LastName, employee.DepartmentID, cast(NULL as varchar(20)), cast(NULL as integer) FROM employee WHERE NOT EXISTS ( SELECT * FROM department WHERE employee.DepartmentID = department.DepartmentID) UNION ALL SELECT cast(NULL as varchar(20)), cast(NULL as integer), department.DepartmentName, department.DepartmentID FROM department WHERE NOT EXISTS ( SELECT * FROM employee WHERE employee.DepartmentID = department.DepartmentID)
A self-join is joining a table to itself.
If there were two separate tables for employees and a query which requested employees in the first table having the same country as employees in the second table, a normal join operation could be used to find the answer table. However, all the employee information is contained within a single large table.
Consider a modified
Employee table such as the following:
An example solution query could be as follows:
SELECT F.EmployeeID, F.LastName, S.EmployeeID, S.LastName, F.Country FROM Employee F INNER JOIN Employee S ON F.Country = S.Country WHERE F.EmployeeID < S.EmployeeID ORDER BY F.EmployeeID, S.EmployeeID;
Which results in the following table being generated.
For this example:
Sare aliases for the first and second copies of the employee table.
- The condition
F.Country = S.Countryexcludes pairings between employees in different countries. The example question only wanted pairs of employees in the same country.
- The condition
F.EmployeeID < S.EmployeeIDexcludes pairings where the
EmployeeIDof the first employee is greater than or equal to the
EmployeeIDof the second employee. In other words, the effect of this condition is to exclude duplicate pairings and self-pairings. Without it, the following less useful table would be generated (the table below displays only the "Germany" portion of the result):
Only one of the two middle pairings is needed to satisfy the original question, and the topmost and bottommost are of no interest at all in this example.
The effect of an outer join can also be obtained using a UNION ALL between an INNER JOIN and a SELECT of the rows in the "main" table that do not fulfill the join condition. For example,
SELECT employee.LastName, employee.DepartmentID, department.DepartmentName FROM employee LEFT OUTER JOIN department ON employee.DepartmentID = department.DepartmentID;
can also be written as
SELECT employee.LastName, employee.DepartmentID, department.DepartmentName FROM employee INNER JOIN department ON employee.DepartmentID = department.DepartmentID UNION ALL SELECT employee.LastName, employee.DepartmentID, cast(NULL as varchar(20)) FROM employee WHERE NOT EXISTS ( SELECT * FROM department WHERE employee.DepartmentID = department.DepartmentID)
Much work in database-systems has aimed at efficient implementation of joins, because relational systems commonly call for joins, yet face difficulties in optimising their efficient execution. The problem arises because inner joins operate both commutatively and associatively. In practice, this means that the user merely supplies the list of tables for joining and the join conditions to use, and the database system has the task of determining the most efficient way to perform the operation. A query optimizer determines how to execute a query containing joins. A query optimizer has two basic freedoms:
- Join order: Because it joins functions commutatively and associatively, the order in which the system joins tables does not change the final result set of the query. However, join-order could have an enormous impact on the cost of the join operation, so choosing the best join order becomes very important.
- Join method: Given two tables and a join condition, multiple algorithms can produce the result set of the join. Which algorithm runs most efficiently depends on the sizes of the input tables, the number of rows from each table that match the join condition, and the operations required by the rest of the query.
Many join-algorithms treat their inputs differently. One can refer to the inputs to a join as the "outer" and "inner" join operands, or "left" and "right", respectively. In the case of nested loops, for example, the database system will scan the entire inner relation for each row of the outer relation.
One can classify query-plans involving joins as follows:
- using a base table (rather than another join) as the inner operand of each join in the plan
- using a base table as the outer operand of each join in the plan
- neither left-deep nor right-deep; both inputs to a join may themselves result from joins
In the Teradata implementation, specified columns, aggregate functions on columns, or components of date columns from one or more tables are specified using a syntax similar to the definition of a database view: up to 64 columns/column expressions can be specified in a single join index. Optionally, a column that defines the primary key of the composite data may also be specified: on parallel hardware, the column values are used to partition the index's contents across multiple disks. When the source tables are updated interactively by users, the contents of the join index are automatically updated. Any query whose WHERE clause specifies any combination of columns or column expressions that are an exact subset of those defined in a join index (a so-called "covering query") will cause the join index, rather than the original tables and their indexes, to be consulted during query execution.
The Oracle implementation limits itself to using bitmap indexes. A bitmap join index is used for low-cardinality columns (i.e., columns containing fewer than 300 distinct values, according to the Oracle documentation): it combines low-cardinality columns from multiple related tables. The example Oracle uses is that of an inventory system, where different suppliers provide different parts. The schema has three linked tables: two "master tables", Part and Supplier, and a "detail table", Inventory. The last is a many-to-many table linking Supplier to Part, and contains the most rows. Every part has a Part Type, and every supplier is based in the US, and has a State column. There are not more than 60 states+territories in the US, and not more than 300 Part Types. The bitmap join index is defined using a standard three-table join on the three tables above, and specifying the Part_Type and Supplier_State columns for the index. However, it is defined on the Inventory table, even though the columns Part_Type and Supplier_State are "borrowed" from Supplier and Part respectively.
As for Teradata, an Oracle bitmap join index is only utilized to answer a query when the query's WHERE clause specifies columns limited to those that are included in the join index.
Some database systems allow the user to force the system to read the tables in a join in a particular order. This is used when the join optimizer chooses to read the tables in an inefficient order. For example, in MySQL the command
STRAIGHT_JOIN reads the tables in exactly the order listed in the query.
- SQL CROSS JOIN
- Greg Robidoux, "Avoid SQL Server functions in the WHERE clause for Performance", MSSQL Tips, 5/3/2007
- Patrick Wolf, "Inside Oracle APEX "Caution when using PL/SQL functions in a SQL statement", 11/30/2006
- Gregory A. Larsen, "T-SQL Best Practices - Don't Use Scalar Value Functions in Column List or WHERE Clauses", 10/29/2009,
- Simplifying Joins with the USING Keyword
- In Unicode, the bowtie symbol is ⋈ (U+22C8).
- Ask Tom "Oracle support of ANSI joins." Back to basics: inner joins » Eddie Awad's Blog
- Oracle Left Outer Join
- Shah 2005, p. 165
- Adapted from Pratt 2005, pp. 115–6
- Yu & Meng 1998, p. 213
- Oracle Bitmap Join Index. URL: http://www.dba-oracle.com/art_builder_bitmap_join_idx.htm
- Teradata Join Indexes. "Archived copy". Archived from the original on 2012-12-16. Retrieved 2012-06-14.
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