SELECT¶
Synopsis¶
[ WITH with_query [, ...] ]
SELECT [ ALL | DISTINCT ] select_expr [, ...]
[ FROM from_item [, ...] ]
[ WHERE condition ]
[ GROUP BY [ ALL | DISTINCT ] grouping_element [, ...] ]
[ HAVING condition]
[ { UNION | INTERSECT | EXCEPT } [ ALL | DISTINCT ] select ]
[ ORDER BY expression [ ASC | DESC ] [, ...] ]
[ OFFSET count [ { ROW | ROWS } ] ]
[ { LIMIT [ count | ALL ] } ]
where from_item
is one of
table_name [ [ AS ] alias [ ( column_alias [, ...] ) ] ]
from_item join_type from_item [ ON join_condition | USING ( join_column [, ...] ) ]
and join_type
is one of
[ INNER ] JOIN
LEFT [ OUTER ] JOIN
RIGHT [ OUTER ] JOIN
FULL [ OUTER ] JOIN
CROSS JOIN
and grouping_element
is one of
()
expression
GROUPING SETS ( ( column [, ...] ) [, ...] )
CUBE ( column [, ...] )
ROLLUP ( column [, ...] )
Description¶
Retrieve rows from zero or more tables.
WITH Clause¶
The WITH
clause defines named relations for use within a query.
It allows flattening nested queries or simplifying subqueries.
For example, the following queries are equivalent:
SELECT a, b
FROM (
SELECT a, MAX(b) AS b FROM t GROUP BY a
) AS x;
WITH x AS (SELECT a, MAX(b) AS b FROM t GROUP BY a)
SELECT a, b FROM x;
This also works with multiple subqueries:
WITH
t1 AS (SELECT a, MAX(b) AS b FROM x GROUP BY a),
t2 AS (SELECT a, AVG(d) AS d FROM y GROUP BY a)
SELECT t1.*, t2.*
FROM t1
JOIN t2 ON t1.a = t2.a;
Additionally, the relations within a WITH
clause can chain:
WITH
x AS (SELECT a FROM t),
y AS (SELECT a AS b FROM x),
z AS (SELECT b AS c FROM y)
SELECT c FROM z;
Warning
Currently, the SQL for the WITH
clause will be inlined anywhere the named
relation is used. This means that if the relation is used more than once and the query
is non-deterministic, the results may be different each time.
GROUP BY Clause¶
The GROUP BY
clause divides the output of a SELECT
statement into
groups of rows containing matching values. A simple GROUP BY
clause may
contain any expression composed of input columns or it may be an ordinal
number selecting an output column by position (starting at one).
The following queries are equivalent. They both group the output by
the nationkey
input column with the first query using the ordinal
position of the output column and the second query using the input
column name:
SELECT count(*), nationkey FROM customer GROUP BY 2;
SELECT count(*), nationkey FROM customer GROUP BY nationkey;
GROUP BY
clauses can group output by input column names not appearing in
the output of a select statement. For example, the following query generates
row counts for the customer
table using the input column mktsegment
:
SELECT count(*) FROM customer GROUP BY mktsegment;
_col0
-------
29968
30142
30189
29949
29752
(5 rows)
When a GROUP BY
clause is used in a SELECT
statement all output
expressions must be either aggregate functions or columns present in
the GROUP BY
clause.
Complex Grouping Operations
Presto also supports complex aggregations using the GROUPING SETS
, CUBE
and ROLLUP
syntax. This syntax allows users to perform analysis that requires
aggregation on multiple sets of columns in a single query. Complex grouping
operations do not support grouping on expressions composed of input columns.
Only column names or ordinals are allowed.
Complex grouping operations are often equivalent to a UNION ALL
of simple
GROUP BY
expressions, as shown in the following examples. This equivalence
does not apply, however, when the source of data for the aggregation
is non-deterministic.
GROUPING SETS
Grouping sets allow users to specify multiple lists of columns to group on.
The columns not part of a given sublist of grouping columns are set to NULL
.
SELECT * FROM shipping;
origin_state | origin_zip | destination_state | destination_zip | package_weight
--------------+------------+-------------------+-----------------+----------------
California | 94131 | New Jersey | 8648 | 13
California | 94131 | New Jersey | 8540 | 42
New Jersey | 7081 | Connecticut | 6708 | 225
California | 90210 | Connecticut | 6927 | 1337
California | 94131 | Colorado | 80302 | 5
New York | 10002 | New Jersey | 8540 | 3
(6 rows)
GROUPING SETS
semantics are demonstrated by this example query:
SELECT origin_state, origin_zip, destination_state, sum(package_weight)
FROM shipping
GROUP BY GROUPING SETS (
(origin_state),
(origin_state, origin_zip),
(destination_state));
origin_state | origin_zip | destination_state | _col0
--------------+------------+-------------------+-------
New Jersey | NULL | NULL | 225
California | NULL | NULL | 1397
New York | NULL | NULL | 3
California | 90210 | NULL | 1337
California | 94131 | NULL | 60
New Jersey | 7081 | NULL | 225
New York | 10002 | NULL | 3
NULL | NULL | Colorado | 5
NULL | NULL | New Jersey | 58
NULL | NULL | Connecticut | 1562
(10 rows)
The preceding query may be considered logically equivalent to a UNION ALL
of
multiple GROUP BY
queries:
SELECT origin_state, NULL, NULL, sum(package_weight)
FROM shipping GROUP BY origin_state
UNION ALL
SELECT origin_state, origin_zip, NULL, sum(package_weight)
FROM shipping GROUP BY origin_state, origin_zip
UNION ALL
SELECT NULL, NULL, destination_state, sum(package_weight)
FROM shipping GROUP BY destination_state;
However, the query with the complex grouping syntax (GROUPING SETS
, CUBE
or ROLLUP
) will only read from the underlying data source once, while the
query with the UNION ALL
reads the underlying data three times. This is why
queries with a UNION ALL
may produce inconsistent results when the data
source is not deterministic.
CUBE
The CUBE
operator generates all possible grouping sets (i.e. a power set)
for a given set of columns. For example, the query:
SELECT origin_state, destination_state, sum(package_weight)
FROM shipping
GROUP BY CUBE (origin_state, destination_state);
is equivalent to:
SELECT origin_state, destination_state, sum(package_weight)
FROM shipping
GROUP BY GROUPING SETS (
(origin_state, destination_state),
(origin_state),
(destination_state),
());
origin_state | destination_state | _col0
--------------+-------------------+-------
California | New Jersey | 55
California | Colorado | 5
New York | New Jersey | 3
New Jersey | Connecticut | 225
California | Connecticut | 1337
California | NULL | 1397
New York | NULL | 3
New Jersey | NULL | 225
NULL | New Jersey | 58
NULL | Connecticut | 1562
NULL | Colorado | 5
NULL | NULL | 1625
(12 rows)
ROLLUP
The ROLLUP
operator generates all possible subtotals for a given set of
columns. For example, the query:
SELECT origin_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY ROLLUP (origin_state, origin_zip);
origin_state | origin_zip | _col2
--------------+------------+-------
California | 94131 | 60
California | 90210 | 1337
New Jersey | 7081 | 225
New York | 10002 | 3
California | NULL | 1397
New York | NULL | 3
New Jersey | NULL | 225
NULL | NULL | 1625
(8 rows)
is equivalent to:
SELECT origin_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY GROUPING SETS ((origin_state, origin_zip), (origin_state), ());
Combining multiple grouping expressions
Multiple grouping expressions in the same query are interpreted as having cross-product semantics. For example, the following query:
SELECT origin_state, destination_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY
GROUPING SETS ((origin_state, destination_state)),
ROLLUP (origin_zip);
which can be rewritten as:
SELECT origin_state, destination_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY
GROUPING SETS ((origin_state, destination_state)),
GROUPING SETS ((origin_zip), ());
is logically equivalent to:
SELECT origin_state, destination_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY GROUPING SETS (
(origin_state, destination_state, origin_zip),
(origin_state, destination_state));
origin_state | destination_state | origin_zip | _col3
--------------+-------------------+------------+-------
New York | New Jersey | 10002 | 3
California | New Jersey | 94131 | 55
New Jersey | Connecticut | 7081 | 225
California | Connecticut | 90210 | 1337
California | Colorado | 94131 | 5
New York | New Jersey | NULL | 3
New Jersey | Connecticut | NULL | 225
California | Colorado | NULL | 5
California | Connecticut | NULL | 1337
California | New Jersey | NULL | 55
(10 rows)
The ALL
and DISTINCT
quantifiers determine whether duplicate grouping
sets each produce distinct output rows. This is particularly useful when
multiple complex grouping sets are combined in the same query. For example, the
following query:
SELECT origin_state, destination_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY ALL
CUBE (origin_state, destination_state),
ROLLUP (origin_state, origin_zip);
is equivalent to:
SELECT origin_state, destination_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY GROUPING SETS (
(origin_state, destination_state, origin_zip),
(origin_state, origin_zip),
(origin_state, destination_state, origin_zip),
(origin_state, origin_zip),
(origin_state, destination_state),
(origin_state),
(origin_state, destination_state),
(origin_state),
(origin_state, destination_state),
(origin_state),
(destination_state),
());
However, if the query uses the DISTINCT
quantifier for the GROUP BY
:
SELECT origin_state, destination_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY DISTINCT
CUBE (origin_state, destination_state),
ROLLUP (origin_state, origin_zip);
only unique grouping sets are generated:
SELECT origin_state, destination_state, origin_zip, sum(package_weight)
FROM shipping
GROUP BY GROUPING SETS (
(origin_state, destination_state, origin_zip),
(origin_state, origin_zip),
(origin_state, destination_state),
(origin_state),
(destination_state),
());
The default set quantifier is ALL
.
GROUPING Operation
grouping(col1, ..., colN) -> bigint
The grouping operation returns a bit set converted to decimal, indicating which columns are present in a
grouping. It must be used in conjunction with GROUPING SETS
, ROLLUP
, CUBE
or GROUP BY
and its arguments must match exactly the columns referenced in the corresponding GROUPING SETS
,
ROLLUP
, CUBE
or GROUP BY
clause.
To compute the resulting bit set for a particular row, bits are assigned to the argument columns with the rightmost column being the least significant bit. For a given grouping, a bit is set to 0 if the corresponding column is included in the grouping and to 1 otherwise. For example, consider the query below:
SELECT origin_state, origin_zip, destination_state, sum(package_weight),
grouping(origin_state, origin_zip, destination_state)
FROM shipping
GROUP BY GROUPING SETS (
(origin_state),
(origin_state, origin_zip),
(destination_state));
origin_state | origin_zip | destination_state | _col3 | _col4
--------------+------------+-------------------+-------+-------
California | NULL | NULL | 1397 | 3
New Jersey | NULL | NULL | 225 | 3
New York | NULL | NULL | 3 | 3
California | 94131 | NULL | 60 | 1
New Jersey | 7081 | NULL | 225 | 1
California | 90210 | NULL | 1337 | 1
New York | 10002 | NULL | 3 | 1
NULL | NULL | New Jersey | 58 | 6
NULL | NULL | Connecticut | 1562 | 6
NULL | NULL | Colorado | 5 | 6
(10 rows)
The first grouping in the above result only includes the origin_state
column and excludes
the origin_zip
and destination_state
columns. The bit set constructed for that grouping
is 011
where the most significant bit represents origin_state
.
HAVING Clause¶
The HAVING
clause is used in conjunction with aggregate functions and
the GROUP BY
clause to control which groups are selected. A HAVING
clause eliminates groups that do not satisfy the given conditions.
HAVING
filters groups after groups and aggregates are computed.
The following example queries the customer
table and selects groups
with an account balance greater than the specified value:
SELECT count(*), mktsegment, nationkey,
CAST(sum(acctbal) AS bigint) AS totalbal
FROM customer
GROUP BY mktsegment, nationkey
HAVING sum(acctbal) > 5700000
ORDER BY totalbal DESC;
_col0 | mktsegment | nationkey | totalbal
-------+------------+-----------+----------
1272 | AUTOMOBILE | 19 | 5856939
1253 | FURNITURE | 14 | 5794887
1248 | FURNITURE | 9 | 5784628
1243 | FURNITURE | 12 | 5757371
1231 | HOUSEHOLD | 3 | 5753216
1251 | MACHINERY | 2 | 5719140
1247 | FURNITURE | 8 | 5701952
(7 rows)
UNION | INTERSECT | EXCEPT Clause¶
UNION
INTERSECT
and EXCEPT
are all set operations. These clauses are used
to combine the results of more than one select statement into a single result set:
query UNION [ALL | DISTINCT] query
query INTERSECT [DISTINCT] query
query EXCEPT [DISTINCT] query
The argument ALL
or DISTINCT
controls which rows are included in
the final result set. If the argument ALL
is specified all rows are
included even if the rows are identical. If the argument DISTINCT
is specified only unique rows are included in the combined result set.
If neither is specified, the behavior defaults to DISTINCT
. The ALL
argument is not supported for INTERSECT
or EXCEPT
.
Multiple set operations are processed left to right, unless the order is explicitly
specified via parentheses. Additionally, INTERSECT
binds more tightly
than EXCEPT
and UNION
. That means A UNION B INTERSECT C EXCEPT D
is the same as A UNION (B INTERSECT C) EXCEPT D
.
UNION
UNION
combines all the rows that are in the result set from the
first query with those that are in the result set for the second query.
The following is an example of one of the simplest possible UNION
clauses.
It selects the value 13
and combines this result set with a second query
that selects the value 42
:
SELECT 13
UNION
SELECT 42;
_col0
-------
13
42
(2 rows)
The following query demonstrates the difference between UNION
and UNION ALL
.
It selects the value 13
and combines this result set with a second query that
selects the values 42
and 13
:
SELECT 13
UNION
SELECT * FROM (VALUES 42, 13);
_col0
-------
13
42
(2 rows)
SELECT 13
UNION ALL
SELECT * FROM (VALUES 42, 13);
_col0
-------
13
42
13
(2 rows)
INTERSECT
INTERSECT
returns only the rows that are in the result sets of both the first and
the second queries. The following is an example of one of the simplest
possible INTERSECT
clauses. It selects the values 13
and 42
and combines
this result set with a second query that selects the value 13
. Since 42
is only in the result set of the first query, it is not included in the final results.:
SELECT * FROM (VALUES 13, 42)
INTERSECT
SELECT 13;
_col0
-------
13
(2 rows)
EXCEPT
EXCEPT
returns the rows that are in the result set of the first query,
but not the second. The following is an example of one of the simplest
possible EXCEPT
clauses. It selects the values 13
and 42
and combines
this result set with a second query that selects the value 13
. Since 13
is also in the result set of the second query, it is not included in the final result.:
SELECT * FROM (VALUES 13, 42)
EXCEPT
SELECT 13;
_col0
-------
42
(2 rows)
ORDER BY Clause¶
The ORDER BY
clause is used to sort a result set by one or more
output expressions:
ORDER BY expression [ ASC | DESC ] [ NULLS { FIRST | LAST } ] [, ...]
Each expression may be composed of output columns or it may be an ordinal
number selecting an output column by position (starting at one). The
ORDER BY
clause is evaluated after any GROUP BY
or HAVING
clause
and before any OFFSET
, LIMIT
or FETCH FIRST
clause.
The default null ordering is NULLS LAST
, regardless of the ordering direction.
OFFSET Clause¶
The OFFSET
clause is used to discard a number of leading rows
from the result set:
OFFSET count [ ROW | ROWS ]
If the ORDER BY
clause is present, the OFFSET
clause is evaluated
over a sorted result set, and the set remains sorted after the
leading rows are discarded:
SELECT name FROM nation ORDER BY name OFFSET 22;
name
----------------
UNITED KINGDOM
UNITED STATES
VIETNAM
(3 rows)
Otherwise, it is arbitrary which rows are discarded.
If the count specified in the OFFSET
clause equals or exceeds the size
of the result set, the final result is empty.
LIMIT Clause¶
The LIMIT
clause restricts the number of rows in the result set.
LIMIT ALL
is the same as omitting the LIMIT
clause.
LIMIT { count | ALL }
The following example queries a large table, but the limit clause restricts
the output to only have five rows (because the query lacks an ORDER BY
,
exactly which rows are returned is arbitrary):
SELECT orderdate FROM orders LIMIT 5;
o_orderdate
-------------
1996-04-14
1992-01-15
1995-02-01
1995-11-12
1992-04-26
(5 rows)
LIMIT ALL
is the same as omitting the LIMIT
clause.
If the OFFSET
clause is present, the LIMIT
clause is evaluated
after the OFFSET
clause:
SELECT * FROM (VALUES 5, 2, 4, 1, 3) t(x) ORDER BY x OFFSET 2 LIMIT 2;
x
---
3
4
(2 rows)
TABLESAMPLE¶
There are multiple sample methods:
BERNOULLI
Each row is selected to be in the table sample with a probability of the sample percentage. When a table is sampled using the Bernoulli method, all physical blocks of the table are scanned and certain rows are skipped (based on a comparison between the sample percentage and a random value calculated at runtime).
The probability of a row being included in the result is independent from any other row. This does not reduce the time required to read the sampled table from disk. It may have an impact on the total query time if the sampled output is processed further.
SYSTEM
This sampling method divides the table into logical segments of data and samples the table at this granularity. This sampling method either selects all the rows from a particular segment of data or skips it (based on a comparison between the sample percentage and a random value calculated at runtime).
The rows selected in a system sampling will be dependent on which connector is used. For example, when used with Hive, it is dependent on how the data is laid out on HDFS. This method does not guarantee independent sampling probabilities.
Note
Neither of the two methods allow deterministic bounds on the number of rows returned.
Examples:
SELECT *
FROM users TABLESAMPLE BERNOULLI (50);
SELECT *
FROM users TABLESAMPLE SYSTEM (75);
Using sampling with joins:
SELECT o.*, i.*
FROM orders o TABLESAMPLE SYSTEM (10)
JOIN lineitem i TABLESAMPLE BERNOULLI (40)
ON o.orderkey = i.orderkey;
UNNEST¶
UNNEST
can be used to expand an ARRAY or MAP into a relation.
Arrays are expanded into a single column, and maps are expanded into two columns (key, value).
UNNEST
can also be used with multiple arguments, in which case they are expanded into multiple columns,
with as many rows as the highest cardinality argument (the other columns are padded with nulls).
UNNEST
can optionally have a WITH ORDINALITY
clause, in which case an additional ordinality column
is added to the end.
UNNEST
is normally used with a JOIN
and can reference columns
from relations on the left side of the join.
Using a single array column:
SELECT student, score
FROM tests
CROSS JOIN UNNEST(scores) AS t (score);
Using multiple array columns:
SELECT numbers, animals, n, a
FROM (
VALUES
(ARRAY[2, 5], ARRAY['dog', 'cat', 'bird']),
(ARRAY[7, 8, 9], ARRAY['cow', 'pig'])
) AS x (numbers, animals)
CROSS JOIN UNNEST(numbers, animals) AS t (n, a);
numbers | animals | n | a
-----------+------------------+------+------
[2, 5] | [dog, cat, bird] | 2 | dog
[2, 5] | [dog, cat, bird] | 5 | cat
[2, 5] | [dog, cat, bird] | NULL | bird
[7, 8, 9] | [cow, pig] | 7 | cow
[7, 8, 9] | [cow, pig] | 8 | pig
[7, 8, 9] | [cow, pig] | 9 | NULL
(6 rows)
WITH ORDINALITY
clause:
SELECT numbers, n, a
FROM (
VALUES
(ARRAY[2, 5]),
(ARRAY[7, 8, 9])
) AS x (numbers)
CROSS JOIN UNNEST(numbers) WITH ORDINALITY AS t (n, a);
numbers | n | a
-----------+---+---
[2, 5] | 2 | 1
[2, 5] | 5 | 2
[7, 8, 9] | 7 | 1
[7, 8, 9] | 8 | 2
[7, 8, 9] | 9 | 3
(5 rows)
Using a single map column:
SELECT
animals, a, n
FROM (
VALUES
(MAP(ARRAY['dog', 'cat', 'bird'], ARRAY[1, 2, 0])),
(MAP(ARRAY['dog', 'cat'], ARRAY[4, 5]))
) AS x (animals)
CROSS JOIN UNNEST(animals) AS t (a, n);
animals | a | n
----------------------------+------+---
{"cat":2,"bird":0,"dog":1} | dog | 1
{"cat":2,"bird":0,"dog":1} | cat | 2
{"cat":2,"bird":0,"dog":1} | bird | 0
{"cat":5,"dog":4} | dog | 4
{"cat":5,"dog":4} | cat | 5
(5 rows)
Joins¶
Joins allow you to combine data from multiple relations.
CROSS JOIN¶
A cross join returns the Cartesian product (all combinations) of two
relations. Cross joins can either be specified using the explicit
CROSS JOIN
syntax or by specifying multiple relations in the
FROM
clause.
Both of the following queries are equivalent:
SELECT *
FROM nation
CROSS JOIN region;
SELECT *
FROM nation, region;
The nation
table contains 25 rows and the region
table contains 5 rows,
so a cross join between the two tables produces 125 rows:
SELECT n.name AS nation, r.name AS region
FROM nation AS n
CROSS JOIN region AS r
ORDER BY 1, 2;
nation | region
----------------+-------------
ALGERIA | AFRICA
ALGERIA | AMERICA
ALGERIA | ASIA
ALGERIA | EUROPE
ALGERIA | MIDDLE EAST
ARGENTINA | AFRICA
ARGENTINA | AMERICA
...
(125 rows)
Qualifying Column Names¶
When two relations in a join have columns with the same name, the column references must be qualified using the relation alias (if the relation has an alias), or with the relation name:
SELECT nation.name, region.name
FROM nation
CROSS JOIN region;
SELECT n.name, r.name
FROM nation AS n
CROSS JOIN region AS r;
SELECT n.name, r.name
FROM nation n
CROSS JOIN region r;
The following query will fail with the error Column 'name' is ambiguous
:
SELECT name
FROM nation
CROSS JOIN region;
USING¶
The USING
clause allows you to write shorter queries when both tables you
are joining have the same name for the join key.
For example:
SELECT *
FROM table_1
JOIN table_2
ON table_1.key_A = table_2.key_A AND table_1.key_B = table_2.key_B
can be rewritten to:
SELECT *
FROM table_1
JOIN table_2
USING (key_A, key_B)
The output of doing JOIN
with USING
will be one copy of the join key
columns (key_A
and key_B
in the example above) followed by the remaining columns
in table_1
and then the remaining columns in table_2
. Note that the join keys are not
included in the list of columns from the origin tables for the purpose of
referencing them in the query. You cannot access them with a table prefix and
if you run SELECT table_1.*, table_2.*
, the join columns are not included in the output.
The following two queries are equivalent:
SELECT *
FROM (
VALUES
(1, 3, 10),
(2, 4, 20)
) AS table_1 (key_A, key_B, y1)
LEFT JOIN (
VALUES
(1, 3, 100),
(2, 4, 200)
) AS table_2 (key_A, key_B, y2)
USING (key_A, key_B)
-----------------------------
SELECT key_A, key_B, table_1.*, table_2.*
FROM (
VALUES
(1, 3, 10),
(2, 4, 20)
) AS table_1 (key_A, key_B, y1)
LEFT JOIN (
VALUES
(1, 3, 100),
(2, 4, 200)
) AS table_2 (key_A, key_B, y2)
USING (key_A, key_B)
And produce the output:
key_A | key_B | y1 | y2
-------+-------+----+-----
1 | 3 | 10 | 100
2 | 4 | 20 | 200
(2 rows)
Subqueries¶
A subquery is an expression which is composed of a query. The subquery is correlated when it refers to columns outside of the subquery. Logically, the subquery will be evaluated for each row in the surrounding query. The referenced columns will thus be constant during any single evaluation of the subquery.
Note
Support for correlated subqueries is limited. Not every standard form is supported.
EXISTS¶
The EXISTS
predicate determines if a subquery returns any rows:
SELECT name
FROM nation
WHERE EXISTS (SELECT * FROM region WHERE region.regionkey = nation.regionkey)
IN¶
The IN
predicate determines if any values produced by the subquery
are equal to the provided expression. The result of IN
follows the
standard rules for nulls. The subquery must produce exactly one column:
SELECT name
FROM nation
WHERE regionkey IN (SELECT regionkey FROM region)
Scalar Subquery¶
A scalar subquery is a non-correlated subquery that returns zero or
one row. It is an error for the subquery to produce more than one
row. The returned value is NULL
if the subquery produces no rows:
SELECT name
FROM nation
WHERE regionkey = (SELECT max(regionkey) FROM region)
Note
Currently only single column can be returned from the scalar subquery.