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pt-visual-explain

NAME

pt-visual-explain - Format EXPLAIN output as a tree.

SYNOPSIS

Usage

pt-visual-explain [OPTIONS] [FILES]

pt-visual-explain transforms EXPLAIN output into a tree representation of the query plan. If FILE is given, input is read from the file(s). With no FILE, or when FILE is -, read standard input.

Examples

pt-visual-explain <file_containing_explain_output>

pt-visual-explain -c <file_containing_query>

mysql -e "explain select * from mysql.user" | pt-visual-explain

RISKS

Percona Toolkit is mature, proven in the real world, and well tested, but all database tools can pose a risk to the system and the database server. Before using this tool, please:

  • Read the tool’s documentation

  • Review the tool’s known “BUGS”

  • Test the tool on a non-production server

  • Backup your production server and verify the backups

DESCRIPTION

pt-visual-explain reverse-engineers MySQL’s EXPLAIN output into a query execution plan, which it then formats as a left-deep tree – the same way the plan is represented inside MySQL. It is possible to do this by hand, or to read EXPLAIN’s output directly, but it requires patience and expertise. Many people find a tree representation more understandable.

You can pipe input into pt-visual-explain or specify a filename at the command line, including the magical ‘-’ filename, which will read from standard input. It can do two things with the input: parse it for something that looks like EXPLAIN output, or connect to a MySQL instance and run EXPLAIN on the input.

When parsing its input, pt-visual-explain understands three formats: tabular like that shown in the mysql command-line client, vertical like that created by using the G line terminator in the mysql command-line client, and tab separated. It ignores any lines it doesn’t know how to parse.

When executing the input, pt-visual-explain replaces everything in the input up to the first SELECT keyword with ‘EXPLAIN SELECT,’ and then executes the result. You must specify --connect to execute the input as a query.

Either way, it builds a tree from the result set and prints it to standard output. For the following query,

select * from sakila.film_actor join sakila.film using(film_id);

pt-visual-explain generates this query plan:

JOIN
+- Bookmark lookup
|  +- Table
|  |  table          film_actor
|  |  possible_keys  idx_fk_film_id
|  +- Index lookup
|     key            film_actor->idx_fk_film_id
|     possible_keys  idx_fk_film_id
|     key_len        2
|     ref            sakila.film.film_id
|     rows           2
+- Table scan
   rows           952
   +- Table
      table          film
      possible_keys  PRIMARY

The query plan is left-deep, depth-first search, and the tree’s root is the output node – the last step in the execution plan. In other words, read it like this:

1

Table scan the ‘film’ table, which accesses an estimated 952 rows.

2

For each row, find matching rows by doing an index lookup into the film_actor->idx_fk_film_id index with the value from sakila.film.film_id, then a bookmark lookup into the film_actor table.

For more information on how to read EXPLAIN output, please see http://dev.mysql.com/doc/en/explain.html.

MODULES

This program is actually a runnable module, not just an ordinary Perl script. In fact, there are two modules embedded in it. This makes unit testing easy, but it also makes it easy for you to use the parsing and tree-building functionality if you want.

The ExplainParser package accepts a string and parses whatever it thinks looks like EXPLAIN output from it. The synopsis is as follows:

require "pt-visual-explain";
my $p    = ExplainParser->new();
my $rows = $p->parse("some text");
# $rows is an arrayref of hashrefs.

The ExplainTree package accepts a set of rows and turns it into a tree. For convenience, you can also have it delegate to ExplainParser and parse text for you. Here’s the synopsis:

require "pt-visual-explain";
my $e      = ExplainTree->new();
my $tree   = $e->parse("some text", \%options);
my $output = $e->pretty_print($tree);
print $tree;

ALGORITHM

This section explains the algorithm that converts EXPLAIN into a tree. You may be interested in reading this if you want to understand EXPLAIN more fully, or trying to figure out how this works, but otherwise this section will probably not make your life richer.

The tree can be built by examining the id, select_type, and table columns of each row.

The id column is the sequential number of the select. This does not indicate nesting; it just comes from counting SELECT from the left of the SQL statement. It’s like capturing parentheses in a regular expression.

If two adjacent rows have the same id value, they are joined with the standard single-sweep multi-join method.

The select_type column tells a) that a new sub-scope has opened b) what kind of relationship the row has to the previous row c) what kind of operation the row represents.

  • SIMPLE means there are no subqueries or unions in the whole query.

  • PRIMARY means there are, but this is the outermost SELECT.

  • [DEPENDENT] UNION means this result is UNIONed with the previous result (not row; a result might encompass more than one row).

  • UNION RESULT terminates a set of UNIONed results.

  • [DEPENDENT|UNCACHEABLE] SUBQUERY means a new sub-scope is opening. This is the kind of subquery that happens in a WHERE clause, SELECT list or whatnot; it does not return a so-called “derived table.”

  • DERIVED is a subquery in the FROM clause.

Tables that are JOINed all have the same select_type. For example, if you JOIN three tables inside a dependent subquery, they’ll all say the same thing: DEPENDENT SUBQUERY.

The table column usually specifies the table name or alias, but may also say <derivedN> or <unionN,N…N>. If it says <derivedN>, the row represents an access to the temporary table that holds the result of the subquery whose id is N. If it says <unionN,..N> it’s the same thing, but it refers to the results it UNIONs together.

Finally, order matters. If a row’s id is less than the one before it, that means it is dependent on something other than the one before it. For example,

explain select
   (select 1 from sakila.film),
   (select 2 from sakila.film_actor),
   (select 3 from sakila.actor);

| id | select_type | table      |
+----+-------------+------------+
|  1 | PRIMARY     | NULL       |
|  4 | SUBQUERY    | actor      |
|  3 | SUBQUERY    | film_actor |
|  2 | SUBQUERY    | film       |

If the results were in order 2-3-4, that would mean 3 is a subquery of 2, 4 is a subquery of 3. As it is, this means 4 is a subquery of the nearest previous recent row with a smaller id, which is 1. Likewise for 3 and 2.

This structure is hard to programmatically build into a tree for the same reason it’s hard to understand by inspection: there are both forward and backward references. <derivedN> is a forward reference to selectN, while <unionM,N> is a backward reference to selectM and selectN. That makes recursion and other tree-building algorithms hard to get right (NOTE: after implementation, I now see how it would be possible to deal with both forward and backward references, but I have no motivation to change something that works). Consider the following:

select * from (
   select 1 from sakila.actor as actor_1
   union
   select 1 from sakila.actor as actor_2
) as der_1
union
select * from (
   select 1 from sakila.actor as actor_3
   union all
   select 1 from sakila.actor as actor_4
) as der_2;

| id   | select_type  | table      |
+------+--------------+------------+
|  1   | PRIMARY      | <derived2> |
|  2   | DERIVED      | actor_1    |
|  3   | UNION        | actor_2    |
| NULL | UNION RESULT | <union2,3> |
|  4   | UNION        | <derived5> |
|  5   | DERIVED      | actor_3    |
|  6   | UNION        | actor_4    |
| NULL | UNION RESULT | <union5,6> |
| NULL | UNION RESULT | <union1,4> |

This would be a lot easier to work with if it looked like this (we’ve bracketed the id on rows we moved):

| id   | select_type  | table      |
+------+--------------+------------+
| [1]  | UNION RESULT | <union1,4> |
|  1   | PRIMARY      | <derived2> |
| [2]  | UNION RESULT | <union2,3> |
|  2   | DERIVED      | actor_1    |
|  3   | UNION        | actor_2    |
|  4   | UNION        | <derived5> |
| [5]  | UNION RESULT | <union5,6> |
|  5   | DERIVED      | actor_3    |
|  6   | UNION        | actor_4    |

In fact, why not re-number all the ids, so the PRIMARY row becomes 2, and so on? That would make it even easier to read. Unfortunately that would also have the effect of destroying the meaning of the id column, which is important to preserve in the final tree. Also, though it makes it easier to read, it doesn’t make it easier to manipulate programmatically; so it’s fine to leave them numbered as they are.

The goal of re-ordering is to make it easier to figure out which rows are children of which rows in the execution plan. Given the reordered list and some row whose table is <union…> or <derived>, it is easy to find the beginning of the slice of rows that should be child nodes in the tree: you just look for the first row whose ID is the same as the first number in the table.

The next question is how to find the last row that should be a child node of a UNION or DERIVED. We’ll start with DERIVED, because the solution makes UNION easy.

Consider how MySQL numbers the SELECTs sequentially according to their position in the SQL, left-to-right. Since a DERIVED table encloses everything within it in a scope, which becomes a temporary table, there are only two things to think about: its child subqueries and unions (if any), and its next siblings in the scope that encloses it. Its children will all have an id greater than it does, by definition, so any later rows with a smaller id terminate the scope.

Here’s an example. The middle derived table here has a subquery and a UNION to make it a little more complex for the example.

explain select 1
from (
   select film_id from sakila.film limit 1
) as der_1
join (
   select film_id, actor_id, (select count(*) from sakila.rental) as r
   from sakila.film_actor limit 1
   union all
   select 1, 1, 1 from sakila.film_actor as dummy
) as der_2 using (film_id)
join (
   select actor_id from sakila.actor limit 1
) as der_3 using (actor_id);

Here’s the output of EXPLAIN:

| id   | select_type  | table      |
|  1   | PRIMARY      | <derived2> |
|  1   | PRIMARY      | <derived6> |
|  1   | PRIMARY      | <derived3> |
|  6   | DERIVED      | actor      |
|  3   | DERIVED      | film_actor |
|  4   | SUBQUERY     | rental     |
|  5   | UNION        | dummy      |
| NULL | UNION RESULT | <union3,5> |
|  2   | DERIVED      | film       |

The siblings all have id 1, and the middle one we care about is derived3. (Notice MySQL doesn’t execute them in the order they are defined, which is fine). Now notice that MySQL prints out the rows in the opposite order the subqueries were defined: 6, 3, 2. It always seems to do this, and there might be other methods of finding the scope boundaries including looking for the lower boundary of the next largest sibling, but this is a good enough heuristic. We are forced to rely on it for non-DERIVED subqueries, so we rely on it here too. Therefore, we decide that everything greater than or equal to 3 belongs to the DERIVED scope.

The rule for UNION is simple: they consume the entire enclosing scope, and to find the component parts of each one, you find each part’s beginning as referred to in the <unionN,…> definition, and its end is either just before the next one, or if it’s the last part, the end is the end of the scope.

This is only simple because UNION consumes the entire scope, which is either the entire statement, or the scope of a DERIVED table. This is because a UNION cannot be a sibling of another UNION or a table, DERIVED or not. (Try writing such a statement if you don’t see it intuitively). Therefore, you can just find the enclosing scope’s boundaries, and the rest is easy. Notice in the example above, the UNION is over <union3,5>, which includes the row with id 4 – it includes every row between 3 and 5.

Finally, there are non-derived subqueries to deal with as well. In this case we can’t look at siblings to find the end of the scope as we did for DERIVED. We have to trust that MySQL executes depth-first. Here’s an example:

explain
select actor_id,
(
   select count(film_id)
   + (select count(*) from sakila.film)
   from sakila.film join sakila.film_actor using(film_id)
   where exists(
      select * from sakila.actor
      where sakila.actor.actor_id = sakila.film_actor.actor_id
   )
)
from sakila.actor;

| id | select_type        | table      |
|  1 | PRIMARY            | actor      |
|  2 | SUBQUERY           | film       |
|  2 | SUBQUERY           | film_actor |
|  4 | DEPENDENT SUBQUERY | actor      |
|  3 | SUBQUERY           | film       |

In order, the tree should be built like this:

  • See row 1.

  • See row 2. It’s a higher id than 1, so it’s a subquery, along with every other row whose id is greater than 2.

  • Inside this scope, see 2 and 2 and JOIN them. See 4. It’s a higher id than 2, so it’s again a subquery; recurse. After that, see 3, which is also higher; recurse.

But the only reason the nested subquery didn’t include select 3 is because select 4 came first. In other words, if EXPLAIN looked like this,

| id | select_type        | table      |
|  1 | PRIMARY            | actor      |
|  2 | SUBQUERY           | film       |
|  2 | SUBQUERY           | film_actor |
|  3 | SUBQUERY           | film       |
|  4 | DEPENDENT SUBQUERY | actor      |

I would be forced to assume upon seeing select 3 that select 4 is a subquery of it, rather than just being the next sibling in the enclosing scope.

UNION is a little more complicated than just “the entire scope is a UNION,” because the UNION might itself be inside an enclosing scope that’s only indicated by the first item inside the UNION. There are only three kinds of enclosing scopes: UNION, DERIVED, and SUBQUERY. A UNION can’t enclose a UNION, and a DERIVED has its own “scope markers,” but a SUBQUERY in earlier versions could wholly enclose a UNION, like this strange example on the empty table t1:

explain select * from t1 where not exists(
   (select t11.i from t1 t11) union (select t12.i from t1 t12));

|   id | select_type  | table      | Extra                          |
+------+--------------+------------+--------------------------------+
|    1 | PRIMARY      | t1         | const row not found            |
|    2 | SUBQUERY     | NULL       | No tables used                 |
|    3 | SUBQUERY     | NULL       | no matching row in const table |
|    4 | UNION        | t12        | const row not found            |
| NULL | UNION RESULT | <union2,4> |                                |

The UNION’s backward references might make it look like the UNION encloses the subquery, but studying the query makes it clear this isn’t the case. So when a UNION’s first row says SUBQUERY, it is this special case that we cannot repeat starting from MySQL 5.7.

Armed with this knowledge, it’s possible to use recursion to turn the parent-child relationship between all the rows into a tree representing the execution plan.

MySQL prints the rows in execution order, even the forward and backward references. At any given scope, the rows are processed as a left-deep tree. MySQL does not do “bushy” execution plans. It begins with a table, finds a matching row in the next table, and continues till the last table, when it emits a row. When it runs out, it backtracks till it can find the next row and repeats. There are subtleties of course, but this is the basic plan. This is why MySQL transforms all RIGHT OUTER JOINs into LEFT OUTER JOINs and cannot do FULL OUTER JOIN.

This means in any given scope, say

| id   | select_type  | table      |
|  1   | SIMPLE       | tbl1       |
|  1   | SIMPLE       | tbl2       |
|  1   | SIMPLE       | tbl3       |

The execution plan looks like a depth-first traversal of this tree:

      JOIN
     /    \
   JOIN  tbl3
  /    \
tbl1   tbl2

The JOIN might not be a JOIN. It might be a subquery, for example. This comes from the type column of EXPLAIN. The documentation says this is a “join type,” but “access type” may be more accurate, because it’s “how MySQL accesses rows.”

pt-visual-explain decorates the tree significantly more than just turning rows into nodes. Each node may get a series of transformations that turn it into a subtree of more than one node. For example, an index scan not marked with ‘Using index’ must do a bookmark lookup into the table rows; that is a three-node subtree. However, after the above node-ordering and scoping stuff, the rest of the process is pretty simple.

OPTIONS

This tool accepts additional command-line arguments. Refer to the “SYNOPSIS” and usage information for details.

--ask-pass

Prompt for a password when connecting to MySQL.

--charset

short form: -A; type: string

Default character set. If the value is utf8, sets Perl’s binmode on STDOUT to utf8, passes the mysql_enable_utf8 option to DBD::mysql, and runs SET NAMES UTF8 after connecting to MySQL. Any other value sets binmode on STDOUT without the utf8 layer, and runs SET NAMES after connecting to MySQL.

--clustered-pk

Assume that PRIMARY KEY index accesses don’t need to do a bookmark lookup to retrieve rows. This is the case for InnoDB.

--config

type: Array

Read this comma-separated list of config files; if specified, this must be the first option on the command line.

--connect

short form: -c

Treat input as a query, and obtain EXPLAIN output by connecting to a MySQL instance and running EXPLAIN on the query. When this option is given, pt-visual-explain uses the other connection-specific options such as --user to connect to the MySQL instance. If you have a .my.cnf file, it will read it, so you may not need to specify any connection-specific options.

--database

short form: -D; type: string

Connect to this database.

--defaults-file

short form: -F; type: string

Only read mysql options from the given file. You must give an absolute pathname.

--format

type: string; default: tree

Set output format.

The default is a terse pretty-printed tree. The valid values are:

Value  Meaning
=====  ================================================
tree   Pretty-printed terse tree.
dump   Data::Dumper output (see Data::Dumper for more).
--help

Show help and exit.

--host

short form: -h; type: string

Connect to host.

--mysql_ssl

short form: -s; type: int

Create SSL MySQL connection.

--password

short form: -p; type: string

Password to use when connecting. If password contains commas they must be escaped with a backslash: “exam,ple”

--pid

type: string

Create the given PID file. The tool won’t start if the PID file already exists and the PID it contains is different than the current PID. However, if the PID file exists and the PID it contains is no longer running, the tool will overwrite the PID file with the current PID. The PID file is removed automatically when the tool exits.

--port

short form: -P; type: int

Port number to use for connection.

--set-vars

type: Array

Set the MySQL variables in this comma-separated list of variable=value pairs.

By default, the tool sets:

wait_timeout=10000

Variables specified on the command line override these defaults. For example, specifying --set-vars wait_timeout=500 overrides the defaultvalue of 10000.

The tool prints a warning and continues if a variable cannot be set.

--socket

short form: -S; type: string

Socket file to use for connection.

--user

short form: -u; type: string

User for login if not current user.

--version

Show version and exit.

DSN OPTIONS

These DSN options are used to create a DSN. Each option is given like option=value. The options are case-sensitive, so P and p are not the same option. There cannot be whitespace before or after the = and if the value contains whitespace it must be quoted. DSN options are comma-separated. See the percona-toolkit manpage for full details.

  • A

dsn: charset; copy: yes

Default character set.

  • D

dsn: database; copy: yes

Default database.

  • F

dsn: mysql_read_default_file; copy: yes

Only read default options from the given file

  • h

dsn: host; copy: yes

Connect to host.

  • p

dsn: password; copy: yes

Password to use when connecting. If password contains commas they must be escaped with a backslash: “exam,ple”

  • P

dsn: port; copy: yes

Port number to use for connection.

  • S

dsn: mysql_socket; copy: yes

Socket file to use for connection.

  • u

dsn: user; copy: yes

User for login if not current user.

  • s

dsn: mysql_ssl; copy: yes

Create SSL connection

ENVIRONMENT

The environment variable PTDEBUG enables verbose debugging output to STDERR. To enable debugging and capture all output to a file, run the tool like:

PTDEBUG=1 pt-visual-explain ... > FILE 2>&1

Be careful: debugging output is voluminous and can generate several megabytes of output.

ATTENTION

Using <PTDEBUG> might expose passwords. When debug is enabled, all command line parameters are shown in the output.

SYSTEM REQUIREMENTS

You need Perl, DBI, DBD::mysql, and some core packages that ought to be installed in any reasonably new version of Perl.

BUGS

For a list of known bugs, see https://jira.percona.com/projects/PT/issues.

Please report bugs at https://jira.percona.com/projects/PT. Include the following information in your bug report:

  • Complete command-line used to run the tool

  • Tool --version

  • MySQL version of all servers involved

  • Output from the tool including STDERR

  • Input files (log/dump/config files, etc.)

If possible, include debugging output by running the tool with PTDEBUG; see “ENVIRONMENT”.

DOWNLOADING

Visit http://www.percona.com/software/percona-toolkit/ to download the latest release of Percona Toolkit. Or, get the latest release from the command line:

wget percona.com/get/percona-toolkit.tar.gz

wget percona.com/get/percona-toolkit.rpm

wget percona.com/get/percona-toolkit.deb

You can also get individual tools from the latest release:

wget percona.com/get/TOOL

Replace TOOL with the name of any tool.

AUTHORS

Baron Schwartz

ABOUT PERCONA TOOLKIT

This tool is part of Percona Toolkit, a collection of advanced command-line tools for MySQL developed by Percona. Percona Toolkit was forked from two projects in June, 2011: Maatkit and Aspersa. Those projects were created by Baron Schwartz and primarily developed by him and Daniel Nichter. Visit http://www.percona.com/software/ to learn about other free, open-source software from Percona.

VERSION

pt-visual-explain 3.6.0