What is a SQL
JOIN and what are different types?
An illustration from W3schools:
SQL JOIN ?
SQL JOIN is a method to retrieve data from two or more database tables.
What are the different
SQL JOINs ?
There are a total of five
JOINs. They are :
1. JOIN or INNER JOIN 2. OUTER JOIN 2.1 LEFT OUTER JOIN or LEFT JOIN 2.2 RIGHT OUTER JOIN or RIGHT JOIN 2.3 FULL OUTER JOIN or FULL JOIN 3. NATURAL JOIN 4. CROSS JOIN 5. SELF JOIN
1. JOIN or INNER JOIN :
In this kind of a
JOIN, we get all records that match the condition in both tables, and records in both tables that do not match are not reported.
In other words,
INNER JOIN is based on the single fact that: ONLY the matching entries in BOTH the tables SHOULD be listed.
Note that a
JOIN without any other
JOIN keywords (like
LEFT, etc) is an
INNER JOIN. In other words,
a Syntactic sugar for
INNER JOIN (see: Difference between JOIN and INNER JOIN).
2. OUTER JOIN :
OUTER JOIN retrieves
Either, the matched rows from one table and all rows in the other table Or, all rows in all tables (it doesn't matter whether or not there is a match).
There are three kinds of Outer Join :
2.1 LEFT OUTER JOIN or LEFT JOIN
This join returns all the rows from the left table in conjunction with the matching rows from the
right table. If there are no columns matching in the right table, it returns
2.2 RIGHT OUTER JOIN or RIGHT JOIN
JOIN returns all the rows from the right table in conjunction with the matching rows from the
left table. If there are no columns matching in the left table, it returns
2.3 FULL OUTER JOIN or FULL JOIN
LEFT OUTER JOIN and
RIGHT OUTER JOIN. It returns rows from either table when the conditions are met and returns
NULL value when there is no match.
In other words,
OUTER JOIN is based on the fact that: ONLY the matching entries in ONE OF the tables (RIGHT or LEFT) or BOTH of the tables(FULL) SHOULD be listed.
Note that `OUTER JOIN` is a loosened form of `INNER JOIN`.
3. NATURAL JOIN :
It is based on the two conditions :
JOINis made on all the columns with the same name for equality.
- Removes duplicate columns from the result.
This seems to be more of theoretical in nature and as a result (probably) most DBMS don't even bother supporting this.
4. CROSS JOIN :
It is the Cartesian product of the two tables involved. The result of a
CROSS JOIN will not make sense
in most of the situations. Moreover, we won't need this at all (or needs the least, to be precise).
5. SELF JOIN :
It is not a different form of
JOIN, rather it is a
OUTER, etc) of a table to itself.
JOINs based on Operators
Depending on the operator used for a
JOIN clause, there can be two types of
JOINs. They are
- Equi JOIN
- Theta JOIN
1. Equi JOIN :
JOIN type (
OUTER, etc), if we use ONLY the equality operator (=), then we say that
JOIN is an
2. Theta JOIN :
This is same as
EQUI JOIN but it allows all other operators like >, <, >= etc.
Many consider both
EQUI JOINand Theta
JOINs. But I strongly believe that its a mistake and makes the ideas vague. Because
OUTER JOINetc are all connected with the tables and their data whereas
THETA JOINare only connected with the operators we use in the former.
Again, there are many who consider
NATURAL JOINas some sort of "peculiar"
EQUI JOIN. In fact, it is true, because of the first condition I mentioned for
NATURAL JOIN. However, we don't have to restrict that simply to
NATURAL JOINs alone.
OUTER JOINs etc could be an
JOINS are way to query the data that combined together from multiple tables simultaneously.
Types of JOINS:
Concern to RDBMS there are 5-types of joins:
Equi-Join: Combines common records from two tables based on equality condition. Technically, Join made by using equality-operator (=) to compare values of Primary Key of one table and Foreign Key values of another table, hence result set includes common(matched) records from both tables. For implementation see INNER-JOIN.
Natural-Join: It is enhanced version of Equi-Join, in which SELECT operation omits duplicate column. For implementation see INNER-JOIN
Non-Equi-Join: It is reverse of Equi-join where joining condition is uses other than equal operator(=) e.g, !=, <=, >=, >, < or BETWEEN etc. For implementation see INNER-JOIN.
Self-Join:: A customized behavior of join where a table combined with itself; This is typically needed for querying self-referencing tables (or Unary relationship entity). For implementation see INNER-JOINs.
Cartesian Product: It cross combines all records of both tables without any condition. Technically, it returns the result set of a query without WHERE-Clause.
As per SQL concern and advancement, there are 3-types of joins and all RDBMS joins can be achieved using these types of joins.
INNER-JOIN: It merges(or combines) matched rows from two tables. The matching is done based on common columns of tables and their comparing operation. If equality based condition then: EQUI-JOIN performed, otherwise Non-EQUI-Join.
OUTER-JOIN: It merges(or combines) matched rows from two tables and unmatched rows with NULL values. However, can customized selection of un-matched rows e.g, selecting unmatched row from first table or second table by sub-types: LEFT OUTER JOIN and RIGHT OUTER JOIN.
2.1. LEFT Outer JOIN (a.k.a, LEFT-JOIN): Returns matched rows from two tables and unmatched from the LEFT table(i.e, first table) only.
2.2. RIGHT Outer JOIN (a.k.a, RIGHT-JOIN): Returns matched rows from two tables and unmatched from the RIGHT table only.
2.3. FULL OUTER JOIN (a.k.a OUTER JOIN): Returns matched and unmatched from both tables.
CROSS-JOIN: This join does not merges/combines instead it performs Cartesian product.
Note: Self-JOIN can be achieved by either INNER-JOIN, OUTER-JOIN and CROSS-JOIN based on requirement but the table must join with itself.
1.1: INNER-JOIN: Equi-join implementation
SELECT * FROM Table1 A INNER JOIN Table2 B ON A.<Primary-Key> =B.<Foreign-Key>;
1.2: INNER-JOIN: Natural-JOIN implementation
Select A.*, B.Col1, B.Col2 --But no B.ForeignKeyColumn in Select FROM Table1 A INNER JOIN Table2 B On A.Pk = B.Fk;
1.3: INNER-JOIN with NON-Equi-join implementation
Select * FROM Table1 A INNER JOIN Table2 B On A.Pk <= B.Fk;
1.4: INNER-JOIN with SELF-JOIN
Select * FROM Table1 A1 INNER JOIN Table1 A2 On A1.Pk = A2.Fk;
2.1: OUTER JOIN (full outer join)
Select * FROM Table1 A FULL OUTER JOIN Table2 B On A.Pk = B.Fk;
2.2: LEFT JOIN
Select * FROM Table1 A LEFT OUTER JOIN Table2 B On A.Pk = B.Fk;
2.3: RIGHT JOIN
Select * FROM Table1 A RIGHT OUTER JOIN Table2 B On A.Pk = B.Fk;
3.1: CROSS JOIN
Select * FROM TableA CROSS JOIN TableB;
3.2: CROSS JOIN-Self JOIN
Select * FROM Table1 A1 CROSS JOIN Table1 A2;
Select * FROM Table1 A1,Table1 A2;
Interestingly most other answers suffer from these two problems:
- They focus on basic forms of join only
- They (ab)use Venn diagrams, which are an inaccurate tool for visualising joins (they're much better for unions).
I've recently written an article on the topic: A Probably Incomplete, Comprehensive Guide to the Many Different Ways to JOIN Tables in SQL, which I'll summarise here.
First and foremost: JOINs are cartesian products
This is why Venn diagrams explain them so inaccurately, because a JOIN creates a cartesian product between the two joined tables. Wikipedia illustrates it nicely:
The SQL syntax for cartesian products is
CROSS JOIN. For example:
SELECT * -- This just generates all the days in January 2017 FROM generate_series( '2017-01-01'::TIMESTAMP, '2017-01-01'::TIMESTAMP + INTERVAL '1 month -1 day', INTERVAL '1 day' ) AS days(day) -- Here, we're combining all days with all departments CROSS JOIN departments
Which combines all rows from one table with all rows from the other table:
+--------+ +------------+ | day | | department | +--------+ +------------+ | Jan 01 | | Dept 1 | | Jan 02 | | Dept 2 | | ... | | Dept 3 | | Jan 30 | +------------+ | Jan 31 | +--------+
+--------+------------+ | day | department | +--------+------------+ | Jan 01 | Dept 1 | | Jan 01 | Dept 2 | | Jan 01 | Dept 3 | | Jan 02 | Dept 1 | | Jan 02 | Dept 2 | | Jan 02 | Dept 3 | | ... | ... | | Jan 31 | Dept 1 | | Jan 31 | Dept 2 | | Jan 31 | Dept 3 | +--------+------------+
If we just write a comma separated list of tables, we'll get the same:
-- CROSS JOINing two tables: SELECT * FROM table1, table2
INNER JOIN (Theta-JOIN)
INNER JOIN is just a filtered
CROSS JOIN where the filter predicate is called
Theta in relational algebra.
SELECT * -- Same as before FROM generate_series( '2017-01-01'::TIMESTAMP, '2017-01-01'::TIMESTAMP + INTERVAL '1 month -1 day', INTERVAL '1 day' ) AS days(day) -- Now, exclude all days/departments combinations for -- days before the department was created JOIN departments AS d ON day >= d.created_at
Note that the keyword
INNER is optional (except in MS Access).
A special kind of Theta-JOIN is equi JOIN, which we use most. The predicate joins the primary key of one table with the foreign key of another table. If we use the Sakila database for illustration, we can write:
SELECT * FROM actor AS a JOIN film_actor AS fa ON a.actor_id = fa.actor_id JOIN film AS f ON f.film_id = fa.film_id
This combines all actors with their films.
Or also, on some databases:
SELECT * FROM actor JOIN film_actor USING (actor_id) JOIN film USING (film_id)
USING() syntax allows for specifying a column that must be present on either side of a JOIN operation's tables and creates an equality predicate on those two columns.
Other answers have listed this "JOIN type" separately, but that doesn't make sense. It's just a syntax sugar form for equi JOIN, which is a special case of Theta-JOIN or INNER JOIN. NATURAL JOIN simply collects all columns that are common to both tables being joined and joins
USING() those columns. Which is hardly ever useful, because of accidental matches (like
LAST_UPDATE columns in the Sakila database).
Here's the syntax:
SELECT * FROM actor NATURAL JOIN film_actor NATURAL JOIN film
OUTER JOIN is a bit different from
INNER JOIN as it creates a
UNION of several cartesian products. We can write:
-- Convenient syntax: SELECT * FROM a LEFT JOIN b ON <predicate> -- Cumbersome, equivalent syntax: SELECT a.*, b.* FROM a JOIN b ON <predicate> UNION ALL SELECT a.*, NULL, NULL, ..., NULL FROM a WHERE NOT EXISTS ( SELECT * FROM b WHERE <predicate> )
No one wants to write the latter, so we write
OUTER JOIN (which is usually better optimised by databases).
INNER, the keyword
OUTER is optional, here.
OUTER JOIN comes in three flavours:
LEFT [ OUTER ] JOIN: The left table of the
JOINexpression is added to the union as shown above.
RIGHT [ OUTER ] JOIN: The right table of the
JOINexpression is added to the union as shown above.
FULL [ OUTER ] JOIN: Both tables of the
JOINexpression are added to the union as shown above.
All of these can be combined with the keyword
USING() or with
NATURAL (I've actually had a real world use-case for a
NATURAL FULL JOIN recently)
There are some historic, deprecated syntaxes in Oracle and SQL Server, which supported
OUTER JOIN already before the SQL standard had a syntax for this:
-- Oracle SELECT * FROM actor a, film_actor fa, film f WHERE a.actor_id = fa.actor_id(+) AND fa.film_id = f.film_id(+) -- SQL Server SELECT * FROM actor a, film_actor fa, film f WHERE a.actor_id *= fa.actor_id AND fa.film_id *= f.film_id
Having said so, don't use this syntax. I just list this here so you can recognise it from old blog posts / legacy code.
Few people know this, but the SQL standard specifies partitioned
OUTER JOIN (and Oracle implements it). You can write things like this:
WITH -- Using CONNECT BY to generate all dates in January days(day) AS ( SELECT DATE '2017-01-01' + LEVEL - 1 FROM dual CONNECT BY LEVEL <= 31 ), -- Our departments departments(department, created_at) AS ( SELECT 'Dept 1', DATE '2017-01-10' FROM dual UNION ALL SELECT 'Dept 2', DATE '2017-01-11' FROM dual UNION ALL SELECT 'Dept 3', DATE '2017-01-12' FROM dual UNION ALL SELECT 'Dept 4', DATE '2017-04-01' FROM dual UNION ALL SELECT 'Dept 5', DATE '2017-04-02' FROM dual ) SELECT * FROM days LEFT JOIN departments PARTITION BY (department) -- This is where the magic happens ON day >= created_at
Parts of the result:
+--------+------------+------------+ | day | department | created_at | +--------+------------+------------+ | Jan 01 | Dept 1 | | -- Didn't match, but still get row | Jan 02 | Dept 1 | | -- Didn't match, but still get row | ... | Dept 1 | | -- Didn't match, but still get row | Jan 09 | Dept 1 | | -- Didn't match, but still get row | Jan 10 | Dept 1 | Jan 10 | -- Matches, so get join result | Jan 11 | Dept 1 | Jan 10 | -- Matches, so get join result | Jan 12 | Dept 1 | Jan 10 | -- Matches, so get join result | ... | Dept 1 | Jan 10 | -- Matches, so get join result | Jan 31 | Dept 1 | Jan 10 | -- Matches, so get join result
The point here is that all rows from the partitioned side of the join will wind up in the result regardless if the
JOIN matched anything on the "other side of the JOIN". Long story short: This is to fill up sparse data in reports. Very useful!
Seriously? No other answer got this? Of course not, because it doesn't have a native syntax in SQL, unfortunately (just like ANTI JOIN below). But we can use
EXISTS(), e.g. to find all actors who have played in films:
SELECT * FROM actor a WHERE EXISTS ( SELECT * FROM film_actor fa WHERE a.actor_id = fa.actor_id )
WHERE a.actor_id = fa.actor_id predicate acts as the semi join predicate. If you don't believe it, check out execution plans, e.g. in Oracle. You'll see that the database executes a SEMI JOIN operation, not the
This is just the opposite of SEMI JOIN (be careful not to use
NOT IN though, as it has an important caveat)
Here are all the actors without films:
SELECT * FROM actor a WHERE NOT EXISTS ( SELECT * FROM film_actor fa WHERE a.actor_id = fa.actor_id )
Some folks (especially MySQL people) also write ANTI JOIN like this:
SELECT * FROM actor a LEFT JOIN film_actor fa USING (actor_id) WHERE film_id IS NULL
I think the historic reason is performance.
OMG, this one is too cool. I'm the only one to mention it? Here's a cool query:
SELECT a.first_name, a.last_name, f.* FROM actor AS a LEFT OUTER JOIN LATERAL ( SELECT f.title, SUM(amount) AS revenue FROM film AS f JOIN film_actor AS fa USING (film_id) JOIN inventory AS i USING (film_id) JOIN rental AS r USING (inventory_id) JOIN payment AS p USING (rental_id) WHERE fa.actor_id = a.actor_id -- JOIN predicate with the outer query! GROUP BY f.film_id ORDER BY revenue DESC LIMIT 5 ) AS f ON true
It will find the TOP 5 revenue producing films per actor. Every time you need a TOP-N-per-something query,
LATERAL JOIN will be your friend. If you're a SQL Server person, then you know this
JOIN type under the name
SELECT a.first_name, a.last_name, f.* FROM actor AS a OUTER APPLY ( SELECT f.title, SUM(amount) AS revenue FROM film AS f JOIN film_actor AS fa ON f.film_id = fa.film_id JOIN inventory AS i ON f.film_id = i.film_id JOIN rental AS r ON i.inventory_id = r.inventory_id JOIN payment AS p ON r.rental_id = p.rental_id WHERE fa.actor_id = a.actor_id -- JOIN predicate with the outer query! GROUP BY f.film_id ORDER BY revenue DESC LIMIT 5 ) AS f
OK, perhaps that's cheating, because a
LATERAL JOIN or
APPLY expression is really a "correlated subquery" that produces several rows. But if we allow for "correlated subqueries", we can also talk about...
This is only really implemented by Oracle and Informix (to my knowledge), but it can be emulated in PostgreSQL using arrays and/or XML and in SQL Server using XML.
MULTISET produces a correlated subquery and nests the resulting set of rows in the outer query. The below query selects all actors and for each actor collects their films in a nested collection:
SELECT a.*, MULTISET ( SELECT f.* FROM film AS f JOIN film_actor AS fa USING (film_id) WHERE a.actor_id = fa.actor_id ) AS films FROM actor
As you have seen, there are more types of JOIN than just the "boring"
CROSS JOIN that are usually mentioned. More details in my article. And please, stop using Venn diagrams to illustrate them.
I'm going to push my pet peeve: the USING keyword.
If both tables on both sides of the JOIN have their foreign keys properly named (ie, same name, not just "id) then this can be used:
SELECT ... FROM customers JOIN orders USING (customer_id)
I find this very practical, readable, and not used often enough.