I have simplified the query I am firing for brevity as follows
SELECT
1 AS mae
FROM
(SELECT
t.id
FROM transaction t) a
LEFT OUTER JOIN
(SELECT
track_id
FROM attendee) AS b ON a.id = b.track_id
HAVING mae > 0;
Over here there is no aggregation. However, I still have to use having. If I use where, mysql is unable to recognize the column mae.
Why is this so?
In general, aliases defined in the SELECT clause are not available for re-use in the same SELECT -- nor in the WHERE, nor in the ON clauses. This is a true of all SQL dialects. Aliases are allowed in the ORDER BY, on the other hand.
MySQL recognizes column aliases in the HAVING clause. This is so convenient that MySQL has extended the HAVING clause for use with non-aggregation queries. So, your query is using this extension.
One nice feature of this extension is that it allows the reference without using a subquery -- the normal way around this. Because MySQL materializes (almost) all derived tables, this saves overhead in the processing.
Ae you just trying to do a regular join ?
SELECT *
FROM transaction t
JOIN attendee AS b
ON a.id = b.track_id
Related
I have question about priority operation in sql statement. For example:
SELECT t1.c2, COUNT(DISTINCT t2.c1) as count_c1 FROM t1 JOIN t2
WHERE t2.c2 > 1 GROUP BY t1.c2 HAVING count_c1 > 1;
Which filter from this query will be applied first and which last. As I understand condition in HAVING will be last, it means that server generate full record set and after that remove all rows with count_c1 < 1 and return result to client.
Condition under WHERE will be first, it means that server don't even get rows with t2.c2 < 1, but what's about DISTINCT and GROUP BY? Result will be different if server will apply DISTINCT before GROUP BY from the opposite situation(GROUP BY first and DISTINCT second). I can't find anything in documentation about this, may be you help me.
Frist, like Thorsten Kettner said, your SQL syntax is actually invalid. Secondly,
The order of operations I was able to find (source) is as follows:
FROM clause (this includes JOIN's)
WHERE clause
GROUP BY clause
HAVING clause
SELECT clause
ORDER BY clause
The priority operation in SQL in as:
FROM
WHERE
GROUP BY
HAVING
SELECT
ORDER BY
You have learn about it in MVA here
The DBMS is free to either join first and then apply the WHERE clause or use the WHERE clause already to restrict rows to join.
Aggregation. Grouping by c2, counting distinct c1 in the process. You count distinct c1 per c2.
The HAVING clause (as it is dealing with the aggregated rows). MySQL allows for an alias name here, which doesn't comply with standard SQL (as the SELECT clause is not yet executed).
SELECT clause: Show the results.
For simplicity, assume all relevant fields are NOT NULL.
You can do:
SELECT
table1.this, table2.that, table2.somethingelse
FROM
table1, table2
WHERE
table1.foreignkey = table2.primarykey
AND (some other conditions)
Or else:
SELECT
table1.this, table2.that, table2.somethingelse
FROM
table1 INNER JOIN table2
ON table1.foreignkey = table2.primarykey
WHERE
(some other conditions)
Do these two work on the same way in MySQL?
INNER JOIN is ANSI syntax that you should use.
It is generally considered more readable, especially when you join lots of tables.
It can also be easily replaced with an OUTER JOIN whenever a need arises.
The WHERE syntax is more relational model oriented.
A result of two tables JOINed is a cartesian product of the tables to which a filter is applied which selects only those rows with joining columns matching.
It's easier to see this with the WHERE syntax.
As for your example, in MySQL (and in SQL generally) these two queries are synonyms.
Also, note that MySQL also has a STRAIGHT_JOIN clause.
Using this clause, you can control the JOIN order: which table is scanned in the outer loop and which one is in the inner loop.
You cannot control this in MySQL using WHERE syntax.
Others have pointed out that INNER JOIN helps human readability, and that's a top priority, I agree.
Let me try to explain why the join syntax is more readable.
A basic SELECT query is this:
SELECT stuff
FROM tables
WHERE conditions
The SELECT clause tells us what we're getting back; the FROM clause tells us where we're getting it from, and the WHERE clause tells us which ones we're getting.
JOIN is a statement about the tables, how they are bound together (conceptually, actually, into a single table).
Any query elements that control the tables - where we're getting stuff from - semantically belong to the FROM clause (and of course, that's where JOIN elements go). Putting joining-elements into the WHERE clause conflates the which and the where-from, that's why the JOIN syntax is preferred.
Applying conditional statements in ON / WHERE
Here I have explained the logical query processing steps.
Reference: Inside Microsoft® SQL Server™ 2005 T-SQL Querying
Publisher: Microsoft Press
Pub Date: March 07, 2006
Print ISBN-10: 0-7356-2313-9
Print ISBN-13: 978-0-7356-2313-2
Pages: 640
Inside Microsoft® SQL Server™ 2005 T-SQL Querying
(8) SELECT (9) DISTINCT (11) TOP <top_specification> <select_list>
(1) FROM <left_table>
(3) <join_type> JOIN <right_table>
(2) ON <join_condition>
(4) WHERE <where_condition>
(5) GROUP BY <group_by_list>
(6) WITH {CUBE | ROLLUP}
(7) HAVING <having_condition>
(10) ORDER BY <order_by_list>
The first noticeable aspect of SQL that is different than other programming languages is the order in which the code is processed. In most programming languages, the code is processed in the order in which it is written. In SQL, the first clause that is processed is the FROM clause, while the SELECT clause, which appears first, is processed almost last.
Each step generates a virtual table that is used as the input to the following step. These virtual tables are not available to the caller (client application or outer query). Only the table generated by the final step is returned to the caller. If a certain clause is not specified in a query, the corresponding step is simply skipped.
Brief Description of Logical Query Processing Phases
Don't worry too much if the description of the steps doesn't seem to make much sense for now. These are provided as a reference. Sections that come after the scenario example will cover the steps in much more detail.
FROM: A Cartesian product (cross join) is performed between the first two tables in the FROM clause, and as a result, virtual table VT1 is generated.
ON: The ON filter is applied to VT1. Only rows for which the <join_condition> is TRUE are inserted to VT2.
OUTER (join): If an OUTER JOIN is specified (as opposed to a CROSS JOIN or an INNER JOIN), rows from the preserved table or tables for which a match was not found are added to the rows from VT2 as outer rows, generating VT3. If more than two tables appear in the FROM clause, steps 1 through 3 are applied repeatedly between the result of the last join and the next table in the FROM clause until all tables are processed.
WHERE: The WHERE filter is applied to VT3. Only rows for which the <where_condition> is TRUE are inserted to VT4.
GROUP BY: The rows from VT4 are arranged in groups based on the column list specified in the GROUP BY clause. VT5 is generated.
CUBE | ROLLUP: Supergroups (groups of groups) are added to the rows from VT5, generating VT6.
HAVING: The HAVING filter is applied to VT6. Only groups for which the <having_condition> is TRUE are inserted to VT7.
SELECT: The SELECT list is processed, generating VT8.
DISTINCT: Duplicate rows are removed from VT8. VT9 is generated.
ORDER BY: The rows from VT9 are sorted according to the column list specified in the ORDER BY clause. A cursor is generated (VC10).
TOP: The specified number or percentage of rows is selected from the beginning of VC10. Table VT11 is generated and returned to the caller.
Therefore, (INNER JOIN) ON will filter the data (the data count of VT will be reduced here itself) before applying the WHERE clause. The subsequent join conditions will be executed with filtered data which improves performance. After that, only the WHERE condition will apply filter conditions.
(Applying conditional statements in ON / WHERE will not make much difference in few cases. This depends on how many tables you have joined and the number of rows available in each join tables)
The implicit join ANSI syntax is older, less obvious, and not recommended.
In addition, the relational algebra allows interchangeability of the predicates in the WHERE clause and the INNER JOIN, so even INNER JOIN queries with WHERE clauses can have the predicates rearranged by the optimizer.
I recommend you write the queries in the most readable way possible.
Sometimes this includes making the INNER JOIN relatively "incomplete" and putting some of the criteria in the WHERE simply to make the lists of filtering criteria more easily maintainable.
For example, instead of:
SELECT *
FROM Customers c
INNER JOIN CustomerAccounts ca
ON ca.CustomerID = c.CustomerID
AND c.State = 'NY'
INNER JOIN Accounts a
ON ca.AccountID = a.AccountID
AND a.Status = 1
Write:
SELECT *
FROM Customers c
INNER JOIN CustomerAccounts ca
ON ca.CustomerID = c.CustomerID
INNER JOIN Accounts a
ON ca.AccountID = a.AccountID
WHERE c.State = 'NY'
AND a.Status = 1
But it depends, of course.
Implicit joins (which is what your first query is known as) become much much more confusing, hard to read, and hard to maintain once you need to start adding more tables to your query. Imagine doing that same query and type of join on four or five different tables ... it's a nightmare.
Using an explicit join (your second example) is much more readable and easy to maintain.
I'll also point out that using the older syntax is more subject to error. If you use inner joins without an ON clause, you will get a syntax error. If you use the older syntax and forget one of the join conditions in the where clause, you will get a cross join. The developers often fix this by adding the distinct keyword (rather than fixing the join because they still don't realize the join itself is broken) which may appear to cure the problem but will slow down the query considerably.
Additionally for maintenance if you have a cross join in the old syntax, how will the maintainer know if you meant to have one (there are situations where cross joins are needed) or if it was an accident that should be fixed?
Let me point you to this question to see why the implicit syntax is bad if you use left joins.
Sybase *= to Ansi Standard with 2 different outer tables for same inner table
Plus (personal rant here), the standard using the explicit joins is over 20 years old, which means implicit join syntax has been outdated for those 20 years. Would you write application code using a syntax that has been outdated for 20 years? Why do you want to write database code that is?
The SQL:2003 standard changed some precedence rules so a JOIN statement takes precedence over a "comma" join. This can actually change the results of your query depending on how it is setup. This cause some problems for some people when MySQL 5.0.12 switched to adhering to the standard.
So in your example, your queries would work the same. But if you added a third table:
SELECT ... FROM table1, table2 JOIN table3 ON ... WHERE ...
Prior to MySQL 5.0.12, table1 and table2 would be joined first, then table3. Now (5.0.12 and on), table2 and table3 are joined first, then table1. It doesn't always change the results, but it can and you may not even realize it.
I never use the "comma" syntax anymore, opting for your second example. It's a lot more readable anyway, the JOIN conditions are with the JOINs, not separated into a separate query section.
They have a different human-readable meaning.
However, depending on the query optimizer, they may have the same meaning to the machine.
You should always code to be readable.
That is to say, if this is a built-in relationship, use the explicit join. if you are matching on weakly related data, use the where clause.
I know you're talking about MySQL, but anyway:
In Oracle 9 explicit joins and implicit joins would generate different execution plans. AFAIK that has been solved in Oracle 10+: there's no such difference anymore.
If you are often programming dynamic stored procedures, you will fall in love with your second example (using where). If you have various input parameters and lots of morph mess, then that is the only way. Otherwise, they both will run the same query plan so there is definitely no obvious difference in classic queries.
ANSI join syntax is definitely more portable.
I'm going through an upgrade of Microsoft SQL Server, and I would also mention that the =* and *= syntax for outer joins in SQL Server is not supported (without compatibility mode) for 2005 SQL server and later.
I have two points for the implicit join (The second example):
Tell the database what you want, not what it should do.
You can write all tables in a clear list that is not cluttered by join conditions. Then you can much easier read what tables are all mentioned. The conditions come all in the WHERE part, where they are also all lined up one below the other. Using the JOIN keyword mixes up tables and conditions.
Does this query
SELECT * FROM `people` WHERE `country` IN (
SELECT `id` FROM `country` WHERE `available`
)
search for available coutries for each person or it does it once and is as fast as possible?
Maybe it's a good idea to use INNER JOIN to ignore those people whose countries are not available?
Or maybe it's a good idea to split this into two queries? (first select all available countries)?
What's the best method?
If you are using a newer version of MySQL and be careful not to add much complexity on the subquery, the MySQL query optimizer will automatically replace the subquery by a join, see this:
http://dev.mysql.com/doc/refman/5.6/en/subquery-optimization.html
In MySQL, a subquery must satisfy these criteria to be handled as a
semi-join:
It must be an IN (or =ANY) subquery that appears at the top level of
the WHERE or ON clause, possibly as a term in an AND expression. For
example:
SELECT ... FROM ot1, ... WHERE (oe1, ...) IN (SELECT ie1, ... FROM
it1, ... WHERE ...); Here, ot_i and it_i represent tables in the outer
and inner parts of the query, and oe_i and ie_i represent expressions
that refer to columns in the outer and inner tables.
It must be a single SELECT without UNION constructs.
It must not contain a GROUP BY or HAVING clause or aggregate
functions.
It must not have ORDER BY with LIMIT.
The number of outer and inner tables together must be less than the
maximum number of tables permitted in a join.
The subquery may be correlated or uncorrelated. DISTINCT is permitted,
as is LIMIT unless ORDER BY is also used.
I have the following query which both tables are huge. The query were very slow and I need your idea to optimize this query or do you have any other solution?
SELECT c.EstablishmentID,
(SELECT COUNT(ID)
FROM cleanpoi
WHERE EstablishmentID=c.EstablishmentID OR EstablishmentID
IN (SELECT ChildEstablishmentID
FROM crawlerchildren
WHERE ParentEstablishmentID=c.EstablishmentID)
) POI
FROM crawler c
GROUP BY c.EstablishmentID
BTW, I have the appropriate indexes applied.
UPDATE:
Okay, I have attached the explain result.
Try it by using JOIN
SELECT c.EstablishmentID, COUNT(d.ID)
FROM crawler c
LEFT JOIN cleanpoi d
ON c.establishmentid = d.establishmentID
LEFT JOIN
(
SELECT DISTINCT ChildEstablishmentID
FROM crawlerchildren
) e ON e.ParentEstablishmentID = c.EstablishmentID
GROUP BY c.EstablishmentID
IN() and NOT IN() subqueries are poorly optimized:
MySQL executes the subquery as a dependent subquery for each row in the outer query. This is a frequent cause of serious performance problems in MySQL 5.5 and older versions. The query probably should be rewritten as a JOIN or a LEFT OUTER JOIN, respectively.
Non-deterministic GROUP BY:
The SQL retrieves columns that are neither in an aggregate function nor the GROUP BY expression, so these values will be non-deterministic in the result.
GROUP BY or ORDER BY on different tables:
This will force the use of a temporary table and filesort, which can be a huge performance problem and can consume large amounts of memory and temporary space on disk.
I came across writing the query in differnt ways like shown below
Type-I
SELECT JS.JobseekerID
, JS.FirstName
, JS.LastName
, JS.Currency
, JS.AccountRegDate
, JS.LastUpdated
, JS.NoticePeriod
, JS.Availability
, C.CountryName
, S.SalaryAmount
, DD.DisciplineName
, DT.DegreeLevel
FROM Jobseekers JS
INNER
JOIN Countries C
ON JS.CountryID = C.CountryID
INNER
JOIN SalaryBracket S
ON JS.MinSalaryID = S.SalaryID
INNER
JOIN DegreeDisciplines DD
ON JS.DegreeDisciplineID = DD.DisciplineID
INNER
JOIN DegreeType DT
ON JS.DegreeTypeID = DT.DegreeTypeID
WHERE
JS.ShowCV = 'Yes'
Type-II
SELECT JS.JobseekerID
, JS.FirstName
, JS.LastName
, JS.Currency
, JS.AccountRegDate
, JS.LastUpdated
, JS.NoticePeriod
, JS.Availability
, C.CountryName
, S.SalaryAmount
, DD.DisciplineName
, DT.DegreeLevel
FROM Jobseekers JS, Countries C, SalaryBracket S, DegreeDisciplines DD
, DegreeType DT
WHERE
JS.CountryID = C.CountryID
AND JS.MinSalaryID = S.SalaryID
AND JS.DegreeDisciplineID = DD.DisciplineID
AND JS.DegreeTypeID = DT.DegreeTypeID
AND JS.ShowCV = 'Yes'
I am using Mysql database
Both works really well, But I am wondering
which is best practice to use all time for any situation?
Performance wise which is better one?(Say the database as a millions records)
Any advantages of one over the other?
Is there any tool where I can check which is better query?
Thanks in advance
1- It's a no brainer, use the Type I
2- The type II join are also called 'implicit join', whereas the type I are called 'explicit join'. With modern DBMS, you will not have any performance problem with normal query. But I think with some big complex multi join query, the DBMS could have issue with the implicit join. Using explicit join only could improve your explain plan, so faster result !
3- So performance could be an issue, but most important maybe, the readability is improve for further maintenance. Explicit join explain exactly what you want to join on what field, whereas implicit join doesn't show if you make a join or a filter. The Where clause is for filter, not for join !
And a big big point for explicit join : outer join are really annoying with implicit join. It is so hard to read when you want multiple join with outer join that explicit join are THE solution.
4- Execution plan are what you need (See the doc)
Some duplicates :
Explicit vs implicit SQL joins
SQL join: where clause vs. on clause
INNER JOIN ON vs WHERE clause
in the most code i've seen, those querys are done like your Type-II - but i think Type-I is better because of readability (and more logic - a join is a join, so you should write it as a join (althoug the second one is just another writing style for inner joins)).
in performance, there shouldn't be a difference (if there is one, i think the Type-I would be a bit faster).
Look at "Explain"-syntax
http://dev.mysql.com/doc/refman/5.1/en/explain.html
My suggestion.
Update all your tables with some amount of records. Access the MySQL console and run SQL both command one by one. You can see the time execution time in the console.
For the two queries you mentioned (each with only inner joins) any modern database's query optimizer should produce exactly the same query plan, and thus the same performance.
For MySQL, if you prefix the query with EXPLAIN, it will spit out information about the query plan (instead of running the query). If the information from both queries is the same, them the query plan is the same, and the performance will be identical. From the MySQL Reference Manual:
EXPLAIN returns a row of information
for each table used in the SELECT
statement. The tables are listed in
the output in the order that MySQL
would read them while processing the
query. MySQL resolves all joins using
a nested-loop join method. This means
that MySQL reads a row from the first
table, and then finds a matching row
in the second table, the third table,
and so on. When all tables are
processed, MySQL outputs the selected
columns and backtracks through the
table list until a table is found for
which there are more matching rows.
The next row is read from this table
and the process continues with the
next table.
When the EXTENDED keyword is used,
EXPLAIN produces extra information
that can be viewed by issuing a SHOW
WARNINGS statement following the
EXPLAIN statement. This information
displays how the optimizer qualifies
table and column names in the SELECT
statement, what the SELECT looks like
after the application of rewriting and
optimization rules, and possibly other
notes about the optimization process.
As to which syntax is better? That's up to you, but once you move beyond inner joins to outer joins, you'll need to use the newer syntax, since there's no standard for describing outer joins using the older implicit join syntax.