# General rules for simplifying SQL statements

I'm looking for some "inference rules" (similar to set operation rules or logic rules) which I can use to reduce a SQL query in complexity or size. Does there exist something like that? Any papers, any tools? Any equivalencies that you found on your own? It's somehow similar to query optimization, but not in terms of performance.

To state it different: Having a (complex) query with JOINs, SUBSELECTs, UNIONs is it possible (or not) to reduce it to a simpler, equivalent SQL statement, which is producing the same result, by using some transformation rules?

So, I'm looking for equivalent transformations of SQL statements like the fact that most SUBSELECTs can be rewritten as a JOIN.

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+1 Nice question; I look forward to seeing the answers. –  Carl Manaster Jul 1 '09 at 14:17
My approach is to learn relational theory in general and relational algebra in particular. Then learn to spot the constructs used in SQL to implement operators from the relational algebra (e.g. universal quantification a.k.a. division) and calculus (e.g. existential quantification). The gotcha is that SQL has features not found in the relational model e.g. nulls, which are probably best refactored away anyhow. Recommended reading: SQL and Relational Theory: How to Write Accurate SQL Code By C. J. Date. –  onedaywhen Mar 13 '12 at 16:22

To state it different: Having a (complex) query with JOINs, SUBSELECTs, UNIONs is it possible (or not) to reduce it to a simpler, equivalent SQL statement, which is producing the same result, by using some transformation rules?

That's exactly what optimizers do for a living (not that I'm saying they always do this well).

Since `SQL` is a set based language, there are usually more than one way to transform one query to other.

Like this query:

``````SELECT  *
FROM    mytable
WHERE   col1 > @value1 OR col2 < @value2
``````

can be transformed into this:

``````SELECT  *
FROM    mytable
WHERE   col1 > @value1
UNION
SELECT  *
FROM    mytable
WHERE   col2 < @value2
``````

or this:

``````SELECT  mo.*
FROM    (
SELECT  id
FROM    mytable
WHERE   col1 > @value1
UNION
SELECT  id
FROM    mytable
WHERE   col2 < @value2
) mi
JOIN    mytable mo
ON      mo.id = mi.id
``````

, which look uglier but can yield better execution plans.

One of the most common things to do is replacing this query:

``````SELECT  *
FROM    mytable
WHERE   col IN
(
SELECT  othercol
FROM    othertable
)
``````

with this one:

``````SELECT  *
FROM    mytable mo
WHERE   EXISTS
(
SELECT  NULL
FROM    othertable o
WHERE   o.othercol = mo.col
)
``````

In some `RDBMS`'s (like `PostgreSQL`), `DISTINCT` and `GROUP BY` use the different execution plans, so sometimes it's better to replace one with the other:

``````SELECT  mo.grouper,
(
SELECT  SUM(col)
FROM    mytable mi
WHERE   mi.grouper = mo.grouper
)
FROM    (
SELECT  DISTINCT grouper
FROM    mytable
) mo
``````

vs.

``````SELECT  mo.grouper, SUM(col)
FROM    mytable
GROUP BY
mo.grouper
``````

In `PostgreSQL`, `DISTINCT` sorts and `GROUP BY` hashes.

`MySQL` lacks `FULL OUTER JOIN`, so it can be rewritten as folloing:

``````SELECT  t1.col1, t2.col2
FROM    table1 t1
LEFT OUTER JOIN
table2 t2
ON      t1.id = t2.id
``````

vs.

``````SELECT  t1.col1, t2.col2
FROM    table1 t1
LEFT JOIN
table2 t2
ON      t1.id = t2.id
UNION ALL
SELECT  NULL, t2.col2
FROM    table1 t1
RIGHT JOIN
table2 t2
ON      t1.id = t2.id
WHERE   t1.id IS NULL
``````

, but see this article in my blog on how to do this more efficiently in `MySQL`:

This hierarchical query in `Oracle`:

``````SELECT  DISTINCT(animal_id) AS animal_id
FROM    animal
animal_id = :id
CONNECT BY
PRIOR animal_id IN (father, mother)
ORDER BY
animal_id
``````

can be transformed to this:

``````SELECT  DISTINCT(animal_id) AS animal_id
FROM    (
SELECT  0 AS gender, animal_id, father AS parent
FROM    animal
UNION ALL
SELECT  1, animal_id, mother
FROM    animal
)
animal_id = :id
CONNECT BY
parent = PRIOR animal_id
ORDER BY
animal_id
``````

, the latter one being more performant.

To find all ranges that overlap the given range, you can use the following query:

``````SELECT  *
FROM    ranges
WHERE   end_date >= @start
AND start_date <= @end
``````

, but in `SQL Server` this more complex query yields same results faster:

``````SELECT  *
FROM    ranges
WHERE   (start_date > @start AND start_date <= @end)
OR (@start BETWEEN start_date AND end_date)
``````

, and believe it or not, I have an article in my blog on this too:

`SQL Server` also lacks an efficient way to do cumulative aggregates, so this query:

``````SELECT  mi.id, SUM(mo.value) AS running_sum
FROM    mytable mi
JOIN    mytable mo
ON      mo.id <= mi.id
GROUP BY
mi.id
``````

can be more efficiently rewritten using, Lord help me, cursors (you heard me right: `cursors`, `more efficiently` and `SQL Server` in one sentence).

There is a certain kind of query commonly met in financial applications that searches for the effective rate for a currency, like this one in `Oracle`:

``````SELECT  TO_CHAR(SUM(xac_amount * rte_rate), 'FM999G999G999G999G999G999D999999')
FROM    t_transaction x
JOIN    t_rate r
ON      (rte_currency, rte_date) IN
(
SELECT  xac_currency, MAX(rte_date)
FROM    t_rate
WHERE   rte_currency = xac_currency
AND rte_date <= xac_date
)
``````

This query can be heavily rewritten to use an equality condition which allows a `HASH JOIN` instead of `NESTED LOOPS`:

``````WITH v_rate AS
(
SELECT  cur_id AS eff_currency, dte_date AS eff_date, rte_rate AS eff_rate
FROM    (
SELECT  cur_id, dte_date,
(
SELECT  MAX(rte_date)
FROM    t_rate ri
WHERE   rte_currency = cur_id
AND rte_date <= dte_date
) AS rte_effdate
FROM    (
SELECT  (
SELECT  MAX(rte_date)
FROM    t_rate
) - level + 1 AS dte_date
FROM    dual
CONNECT BY
level <=
(
SELECT  MAX(rte_date) - MIN(rte_date)
FROM    t_rate
)
) v_date,
(
SELECT  1 AS cur_id
FROM    dual
UNION ALL
SELECT  2 AS cur_id
FROM    dual
) v_currency
) v_eff
LEFT JOIN
t_rate
ON      rte_currency = cur_id
AND rte_date = rte_effdate
)
SELECT  TO_CHAR(SUM(xac_amount * eff_rate), 'FM999G999G999G999G999G999D999999')
FROM    (
SELECT  xac_currency, TRUNC(xac_date) AS xac_date, SUM(xac_amount) AS xac_amount, COUNT(*) AS cnt
FROM    t_transaction x
GROUP BY
xac_currency, TRUNC(xac_date)
)
JOIN    v_rate
ON      eff_currency = xac_currency
AND eff_date = xac_date
``````

Despite being bulky as a hell, the latter query is `6` times faster.

The main idea here is replacing `<=` with `=`, which requires building an in-memory calendar table. to `JOIN` with.

-
Bug in your first example: UNION does an OR, not an AND. –  Alex Martelli Jul 1 '09 at 14:37
@Alex: right, fixing. –  Quassnoi Jul 1 '09 at 14:38
+1 Those are some great examples of query transformations. It also shows that some of the optimised queries are not actually the simple looking ones e.g. first query vs. third one, which is a pity as one could assume that the "simple" query would be easier to analyse by the optimiser. In other words it seems as optimising is not necessary equal to simplifying –  kristof Jul 1 '09 at 14:59
@Alex: as long as the table has a PRIMARY KEY defined, they are equivalent. A row that satisfies both OR'ed conditions will be selected exactly once, be it with an OR or with a UNION. If the table has exact duplicates (which implies having no PRIMARY KEY), then yes, they will be eliminated with UNION but not with OR. –  Quassnoi Jul 1 '09 at 15:33
I love that you pointed out that in SQl, ugly code is often the best for performance. It drives me crazy when people want to take well-performing code and make it more "elegant" and kill performance. –  HLGEM Jul 13 '11 at 15:20

My approach is to learn relational theory in general and relational algebra in particular. Then learn to spot the constructs used in SQL to implement operators from the relational algebra (e.g. universal quantification a.k.a. division) and calculus (e.g. existential quantification). The gotcha is that SQL has features not found in the relational model e.g. nulls, which are probably best refactored away anyhow. Recommended reading: SQL and Relational Theory: How to Write Accurate SQL Code By C. J. Date.

In this vein, I'm not convinced "the fact that most SUBSELECTs can be rewritten as a JOIN" represents a simplification.

Take this query for example:

``````SELECT c
FROM T1
WHERE c NOT IN ( SELECT c FROM T2 );
``````

Rewrite using JOIN

``````SELECT DISTINCT T1.c
FROM T1 NATURAL LEFT OUTER JOIN T2
WHERE T2.c IS NULL;
``````

The join is more verbose!

Alternatively, recognize the construct is implementing an antijoin on the projection of `c` e.g. pseudo algrbra

``````T1 { c } antijoin T2 { c }
``````

Simplification using relational operators:

``````SELECT c FROM T1 EXCEPT SELECT c FROM T2;
``````
-

Although simplification may not equal optimization, simplification can be important in writing readable SQL code, which is in turn critical to being able to check your SQL code for conceptual correctness (not syntactic correctness, which your development environment should check for you). It seems to me that in an ideal world, we would write the most simple, readable SQL code and then the optimizer would rewrite that SQL code to be in whatever form (perhaps more verbose) would run the fastest.

I have found that thinking of SQL statements as based on set logic is very useful, particularly if I need to combine where clauses or figure out a complex negation of a where clause. I use the laws of boolean algebra in this case.

The most important ones for simplifying a where clause are probably DeMorgan's Laws (note that "·" is "AND" and "+" is "OR"):

• NOT (x · y) = NOT x + NOT y
• NOT (x + y) = NOT x · NOT y

This translates in SQL to:

``````NOT (expr1 AND expr2) -> NOT expr1 OR NOT expr2
NOT (expr1 OR expr2) -> NOT expr1 AND NOT expr2
``````

These laws can be very useful in simplifying where clauses with lots of nested `AND` and `OR` parts.

It is also useful to remember that the statement `field1 IN (value1, value2, ...)` is equivalent to `field1 = value1 OR field1 = value2 OR ...` . This allows you to negate the `IN ()` one of two ways:

``````NOT field1 IN (value1, value2)  -- for longer lists
NOT field1 = value1 AND NOT field1 = value2  -- for shorter lists
``````

A sub-query can be thought of this way also. For example, this negated where clause:

``````NOT (table1.field1 = value1 AND EXISTS (SELECT * FROM table2 WHERE table1.field1 = table2.field2))
``````

can be rewritten as:

``````NOT table1.field1 = value1 OR NOT EXISTS (SELECT * FROM table2 WHERE table1.field1 = table2.field2))
``````

These laws do not tell you how to transform a SQL query using a subquery into one using a join, but boolean logic can help you understand join types and what your query should be returning. For example, with tables `A` and `B`, an `INNER JOIN` is like `A AND B`, a `LEFT OUTER JOIN` is like `(A AND NOT B) OR (A AND B)` which simplifies to `A OR (A AND B)`, and a `FULL OUTER JOIN` is `A OR (A AND B) OR B` which simplifies to `A OR B`.

-
I also find I use the implication rewrite rule a lot i.e. `( P => Q ) <=> ( NOT ( P ) OR Q )` –  onedaywhen Mar 13 '12 at 16:11

Given the nature of SQL, you absolutely have to be aware of the performance implications of any refactoring. Refactoring SQL Applications is a good resource on refactoring with a heavy emphasis on performance (see Chapter 5).

-

Here's a few from working with Oracle 8 & 9 (of course, sometimes doing the opposite might make the query simpler or faster):

Parentheses can be removed if they are not used to override operator precedence. A simple example is when all the boolean operators in your `where` clause are the same: `where ((a or b) or c)` is equivalent to `where a or b or c`.

A sub-query can often (if not always) be merged with the main query to simplify it. In my experience, this often improves performance considerably:

``````select foo.a,
bar.a
from foomatic  foo,
bartastic bar
where foo.id = bar.id and
bar.id = (
select ban.id
from bantabulous ban
where ban.bandana = 42
)
;
``````

is equivalent to

``````select foo.a,
bar.a
from foomatic    foo,
bartastic   bar,
bantabulous ban
where foo.id = bar.id and
bar.id = ban.id and
ban.bandana = 42
;
``````

Using ANSI joins separates a lot of "code monkey" logic from the really interesting parts of the where clause: The previous query is equivalent to

``````select foo.a,
bar.a
from foomatic    foo
join bartastic   bar on bar.id = foo.id
join bantabulous ban on ban.id = bar.id
where ban.bandana = 42
;
``````

If you want to check for the existence of a row, don't use count(*), instead use either `rownum = 1` or put the query in a `where exists` clause to fetch only one row instead of all.

-
Wow, nice suggestion at the end. I never thought to pull the join logic out of the where clause and put it with the table defs, and I haven't seen it used commonly before but it does make a lot of sense. –  Al Crowley Jul 1 '09 at 15:09
+1 on using the newer ANSI join syntax for clarity. –  Jim Ferrans Jul 1 '09 at 16:01

I like everyone on a team to follow a set of standards to make code readable, maintainable, understandable, washable, etc.. :)

• everyone uses the same alias
• no cursors. no loops
• why even think of IN when you can EXISTS
• INDENT
• Consistency in coding style

there is some more stuff here http://stackoverflow.com/questions/976185/what-are-some-of-your-most-useful-database-standards

-
agree. Having standards in a team boosts readability, maintainability and often performance too. At least for readability there are a couple of tools available like e.g. SQLinForm formatter / beautifier –  Guido Jun 1 '13 at 13:12

I like to replace all sort of subselect by join query.

This one is obvious :

``````SELECT  *
FROM    mytable mo
WHERE   EXISTS
(
SELECT  *
FROM    othertable o
WHERE   o.othercol = mo.col
)
``````

by

``````SELECT  mo.*
FROM    mytable mo inner join othertable o on o.othercol = mo.col
``````

And this one is under estimate :

``````SELECT  *
FROM    mytable mo
WHERE   NOT EXISTS
(
SELECT  *
FROM    othertable o
WHERE   o.othercol = mo.col
)
``````

by

``````SELECT  mo.*
FROM    mytable mo left outer join othertable o on o.othercol = mo.col
WHERE   o.othercol is null
``````

It could help the DBMS to choose the good execution plan in a big request.

-
These won't necessarily always give exactly the same results: JOINing on a table will cause duplicates if there is more than one match in the "right" table for any particular value being joined in the "left" table. `EXISTS` and `NOT EXISTS` don't have this issue. (It could be resolved by using `DISTINCT` but that reduces efficiency.) –  Steve Chambers Aug 10 '13 at 11:05