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Hive Joins

Join Syntax

Hive supports the following syntax for joining tables:

join_table:
    table_reference JOIN table_factor [join_condition]
  | table_reference {LEFT|RIGHT|FULL} [OUTER] JOIN table_reference join_condition
  | table_reference LEFT SEMI JOIN table_reference join_condition
  | table_reference CROSS JOIN table_reference [join_condition] (as of Hive 0.10)

table_reference:
    table_factor
  | join_table

table_factor:
    tbl_name [alias]
  | table_subquery alias
  | ( table_references )

join_condition:
    ON equality_expression ( AND equality_expression )*

equality_expression:
    expression = expression

Only equality joins, outer joins, and left semi joins are supported in Hive. Hive does not support join conditions that are not equality conditions as it is very difficult to express such conditions as a map/reduce job. Also, more than two tables can be joined in Hive.

Examples

Some salient points to consider when writing join queries are as follows:

  • Only equality joins are allowed e.g. 
      SELECT a.* FROM a JOIN b ON (a.id = b.id)

      SELECT a.* FROM a JOIN b ON (a.id = b.id AND a.department = b.department)
    are both valid joins, however 
      SELECT a.* FROM a JOIN b ON (a.id <> b.id)
    is NOT allowed
  • More than 2 tables can be joined in the same query e.g. 
      SELECT a.val, b.val, c.val FROM a JOIN b ON (a.key = b.key1) JOIN c ON (c.key = b.key2)
    is a valid join.
  • Hive converts joins over multiple tables into a single map/reduce job if for every table the same column is used in the join clauses e.g. 
      SELECT a.val, b.val, c.val FROM a JOIN b ON (a.key = b.key1) JOIN c ON (c.key = b.key1)
    is converted into a single map/reduce job as only key1 column for b is involved in the join. On the other hand 
      SELECT a.val, b.val, c.val FROM a JOIN b ON (a.key = b.key1) JOIN c ON (c.key = b.key2)
    is converted into two map/reduce jobs because key1 column from b is used in the first join condition and key2 column from b is used in the second one. The first map/reduce job joins a with b and the results are then joined with c in the second map/reduce job.
  • In every map/reduce stage of the join, the last table in the sequence is streamed through the reducers where as the others are buffered. Therefore, it helps to reduce the memory needed in the reducer for buffering the rows for a particular value of the join key by organizing the tables such that the largest tables appear last in the sequence. e.g. in 
      SELECT a.val, b.val, c.val FROM a JOIN b ON (a.key = b.key1) JOIN c ON (c.key = b.key1)
    all the three tables are joined in a single map/reduce job and the values for a particular value of the key for tables a and b are buffered in the memory in the reducers. Then for each row retrieved from c, the join is computed with the buffered rows. Similarly for 
      SELECT a.val, b.val, c.val FROM a JOIN b ON (a.key = b.key1) JOIN c ON (c.key = b.key2)
    there are two map/reduce jobs involved in computing the join. The first of these joins a with b and buffers the values of a while streaming the values of b in the reducers. The second of one of these jobs buffers the results of the first join while streaming the values of c through the reducers.
  • In every map/reduce stage of the join, the table to be streamed can be specified via a hint. e.g. in 
      SELECT /*+ STREAMTABLE(a) */ a.val, b.val, c.val FROM a JOIN b ON (a.key = b.key1) JOIN c ON (c.key = b.key1)
    all the three tables are joined in a single map/reduce job and the values for a particular value of the key for tables b and c are buffered in the memory in the reducers. Then for each row retrieved from a, the join is computed with the buffered rows.
  • LEFT, RIGHT, and FULL OUTER joins exist in order to provide more control over ON clauses for which there is no match. For example, this query: 
      SELECT a.val, b.val FROM a LEFT OUTER JOIN b ON (a.key=b.key)
    will return a row for every row in a. This output row will be a.val,b.val when there is a b.key that equals a.key, and the output row will be a.val,NULL when there is no corresponding b.key. Rows from b which have no corresponding a.key will be dropped. The syntax "FROM a LEFT OUTER JOIN b" must be written on one line in order to understand how it works--a is to the LEFT of b in this query, and so all rows from a are kept; a RIGHT OUTER JOIN will keep all rows from b, and a FULL OUTER JOIN will keep all rows from a and all rows from b. OUTER JOIN semantics should conform to standard SQL specs.
  • Joins occur BEFORE WHERE CLAUSES. So, if you want to restrict the OUTPUT of a join, a requirement should be in the WHERE clause, otherwise it should be in the JOIN clause. A big point of confusion for this issue is partitioned tables: 
      SELECT a.val, b.val FROM a LEFT OUTER JOIN b ON (a.key=b.key)
  WHERE a.ds='2009-07-07' AND b.ds='2009-07-07'
    will join a on b, producing a list of a.val and b.val. The WHERE clause, however, can also reference other columns of a and b that are in the output of the join, and then filter them out. However, whenever a row from the JOIN has found a key for a and no key for b, all of the columns of b will be NULL, including the ds column. This is to say, you will filter out all rows of join output for which there was no valid b.key, and thus you have outsmarted your LEFT OUTER requirement. In other words, the LEFT OUTER part of the join is irrelevant if you reference any column of b in the WHERE clause. Instead, when OUTER JOINing, use this syntax: 
      SELECT a.val, b.val FROM a LEFT OUTER JOIN b
  ON (a.key=b.key AND b.ds='2009-07-07' AND a.ds='2009-07-07')
    ..the result is that the output of the join is pre-filtered, and you won't get post-filtering trouble for rows that have a valid a.key but no matching b.key. The same logic applies to RIGHT and FULL joins.
  • Joins are NOT commutative! Joins are left-associative regardless of whether they are LEFT or RIGHT joins. 
      SELECT a.val1, a.val2, b.val, c.val
  FROM a
  JOIN b ON (a.key = b.key)
  LEFT OUTER JOIN c ON (a.key = c.key)
    ...first joins a on b, throwing away everything in a or b that does not have a corresponding key in the other table. The reduced table is then joined on c. This provides unintuitive results if there is a key that exists in both a and c but not b: The whole row (including a.val1, a.val2, and a.key) is dropped in the "a JOIN b" step because it is not in b. The result does not have a.key in it, so when it is LEFT OUTER JOINed with c, c.val does not make it in because there is no c.key that matches an a.key (because that row from a was removed). Similarly, if this were a RIGHT OUTER JOIN (instead of LEFT), we would end up with an even weirder effect: NULL, NULL, NULL, c.val, because even though we specified a.key=c.key as the join key, we dropped all rows of a that did not match the first JOIN.
    To achieve the more intuitive effect, we should instead do FROM c LEFT OUTER JOIN a ON (c.key = a.key) LEFT OUTER JOIN b ON (c.key = b.key).
  • LEFT SEMI JOIN implements the correlated IN/EXISTS subquery semantics in an efficient way. Since Hive currently does not support IN/EXISTS subqueries, you can rewrite your queries using LEFT SEMI JOIN. The restrictions of using LEFT SEMI JOIN is that the right-hand-side table should only be referenced in the join condition (ON-clause), but not in WHERE- or SELECT-clauses etc. 
      SELECT a.key, a.value
  FROM a
  WHERE a.key in
   (SELECT b.key
    FROM B);
    can be rewritten to: 
       SELECT a.key, a.val
   FROM a LEFT SEMI JOIN b on (a.key = b.key)
  • If all but one of the tables being joined are small, the join can be performed as a map only job. The query 
      SELECT /*+ MAPJOIN(b) */ a.key, a.value
  FROM a join b on a.key = b.key
    does not need a reducer. For every mapper of A, B is read completely. The restriction is that a FULL/RIGHT OUTER JOIN b cannot be performed
  • If the tables being joined are bucketized on the join columns, and the number of buckets in one table is a multiple of the number of buckets in the other table, the buckets can be joined with each other. If table A has 4 buckets and table B has 4 buckets, the following join 
      SELECT /*+ MAPJOIN(b) */ a.key, a.value
  FROM a join b on a.key = b.key
    can be done on the mapper only. Instead of fetching B completely for each mapper of A, only the required buckets are fetched. For the query above, the mapper processing bucket 1 for A will only fetch bucket 1 of B. It is not the default behavior, and is governed by the following parameter 
      set hive.optimize.bucketmapjoin = true
  • If the tables being joined are sorted and bucketized on the join columns, and they have the same number of buckets, a sort-merge join can be performed. The corresponding buckets are joined with each other at the mapper. If both A and B have 4 buckets, 
      SELECT /*+ MAPJOIN(b) */ a.key, a.value
  FROM A a join B b on a.key = b.key
    can be done on the mapper only. The mapper for the bucket for A will traverse the corresponding bucket for B. This is not the default behavior, and the following parameters need to be set: 
      set hive.input.format=org.apache.hadoop.hive.ql.io.BucketizedHiveInputFormat;
  set hive.optimize.bucketmapjoin = true;
  set hive.optimize.bucketmapjoin.sortedmerge = true;
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