Файл: playtox.tk/Tools/phpmyadmin/libraries/advisory_rules.txt
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# phpMyAdmin Advisory rules file
# Use only UNIX style newlines
# This file
is being parsed by Advisor.class.php, which should handle syntax errors
correctly.
# However, PHP Warnings and the like are being consumed by the
phpMyAdmin error handler, so those won't show up
# E.g.: Justification line
is empty because you used an unescape percent sign, sprintf() returns an
empty string and no warning/error is shown
#
# Rule Syntax:
# 'rule'
identifier[the name of the rule] eexpr [an optional
precondition]
# expr [variable or value calculation used for the
test]
# expr [test, if evaluted to 'true' it fires the rule. Use 'value'
to insert the calculated value (without quotes)]
# string [the issue (what
is the problem?)]
# string [the recommendation (how do i fix
it?)]
# formatted-string '|' comma-seperated-expr [the justification
(result of the calculated value / why did this rule fire?)]
#
comma-seperated-expr: expr(,expr)*
# eexpr: [expr] - expr enclosed in []
#
expr: a php code literal with extras:
# - variable names are replaced
with their respective values
# - fired('name of rule') is replaced
with true/false when given rule has been fired. Note however that this is a
very simple rules engine. Rules are only checked in sequential order as
they are written down here. If given rule has not been checked yet, fired()
will always evaluate to false
# - 'value' is replaced with the
calculated value. If it is a string, it will be put within single quotes
#
- other than that you may use any php function, initialized variable
or constant
#
# identifier: A string enclosed in single quotes
# string: A
quoteless string, may contain HTML. Variable names enclosed in curly braces
are replaced with links to directly edit this variable. e.g.
{tmp_table_size}
# formatted-string: You may use classic php sprintf()
string formatting here, the arguments must be appended after a trailing
pipe (|) as mentioned in above syntax
# percent signs (%)
are automatically escaped (%%) in the following cases: When followed by a
space, dot or comma and at the end of the line)
#
# Comments start with
#
#
# Queries
rule 'Uptime below one day'
Uptime
value <
86400
Uptime is less than 1 day, performance tuning may not be
accurate.
To have more accurate averages it is recommended to let the
server run for longer than a day before running this analyzer
The uptime
is only %s | PMA_timespanFormat(Uptime)
rule 'Questions below
1,000'
Questions
value < 1000
Fewer than 1,000 questions have been
run against this server. The recommendations may not be accurate.
Let the
server run for a longer time until it has executed a greater amount of
queries.
Current amount of Questions: %s | Questions
rule 'Percentage of
slow queries' [Questions > 0 && !PMA_DRIZZLE]
Slow_queries /
Questions * 100
value >= 5
There is a lot of slow queries compared to
the overall amount of Queries.
You might want to increase
{long_query_time} or optimize the queries listed in the slow query log
The
slow query rate should be below 5%, your value is %s%. |
round(value,2)
rule 'Slow query rate' [Questions > 0]
(Slow_queries /
Questions * 100) / Uptime
value * 60 * 60 > 1
There is a high
percentage of slow queries compared to the server uptime.
You might want
to increase {long_query_time} or optimize the queries listed in the slow
query log
You have a slow query rate of %s per hour, you should have less
than 1% per hour. | PMA_bytime(value,2)
rule 'Long query time'
[!PMA_DRIZZLE]
long_query_time
value >= 10
long_query_time is set to
10 seconds or more, thus only slow queries that take above 10 seconds are
logged.
It is suggested to set {long_query_time} to a lower value,
depending on your environment. Usually a value of 1-5 seconds is
suggested.
long_query_time is currently set to %ds. | value
rule 'Slow
query logging' [!PMA_DRIZZLE]
log_slow_queries
value == 'OFF'
The slow
query log is disabled.
Enable slow query logging by setting
{log_slow_queries} to 'ON'. This will help troubleshooting badly performing
queries.
log_slow_queries is set to 'OFF'
#
# versions
rule 'Release
Series' [!PMA_DRIZZLE]
version
substr(value,0,1) <= 5 &&
substr(value,2,1) < 1
The MySQL server version less than 5.1.
You
should upgrade, as MySQL 5.1 has improved performance, and MySQL 5.5 even
more so.
Current version: %s | value
rule 'Minor Version' [!
fired('Release Series')]
version
substr(value,0,1) <= 5 &&
substr(value,2,1) < 1 && substr(value,4,2) < 30
Version less
than 5.1.30 (the first GA release of 5.1).
You should upgrade, as recent
versions of MySQL 5.1 have improved performance and MySQL 5.5 even more
so.
Current version: %s | value
rule 'Minor Version' [! fired('Release
Series')]
version
substr(value,0,1) == 5 && substr(value,2,1) ==
5 && substr(value,4,2) < 8
Version less than 5.5.8 (the first
GA release of 5.5).
You should upgrade, to a stable version of MySQL
5.5
Current version: %s | value
rule
'Distribution'
version_comment
preg_match('/source/i',value)
Version is
compiled from source, not a MySQL official binary.
If you did not compile
from source, you may be using a package modified by a distribution. The
MySQL manual only is accurate for official MySQL binaries, not any package
distributions (such as RedHat, Debian/Ubuntu etc).
'source' found in
version_comment
rule
'Distribution'
version_comment
preg_match('/percona/i',value)
The MySQL
manual only is accurate for official MySQL binaries.
Percona documentation
is at http://www.percona.com/docs/wiki/
'percona' found in
version_comment
rule 'Distribution'
version
PMA_DRIZZLE
The MySQL
manual only is accurate for official MySQL binaries.
Drizzle documentation
is at http://docs.drizzle.org/
Version string (%s) matches Drizzle
versioning scheme | value
rule 'MySQL Architecture'
system_memory
value
> 3072*1024 && !preg_match('/64/',version_compile_machine)
&& !preg_match('/64/',version_compile_os)
MySQL is not compiled as
a 64-bit package.
Your memory capacity is above 3 GiB (assuming the Server
is on localhost), so MySQL might not be able to access all of your memory.
You might want to consider installing the 64-bit version of
MySQL.
Available memory on this host: %s | implode('
',PMA_formatByteDown(value*1024, 2, 2))
#
# Query cache
# Lame: 'ON' == 0
is true, so you need to compare 'ON' == '0'
rule 'Query cache disabled'
[!PMA_DRIZZLE]
query_cache_size
value == 0 || query_cache_type == 'OFF'
|| query_cache_type == '0'
The query cache is not enabled.
The query
cache is known to greatly improve performance if configured correctly.
Enable it by setting {query_cache_size} to a 2 digit MiB value and setting
{query_cache_type} to 'ON'. <b>Note:</b> If you are using
memcached, ignore this recommendation.
query_cache_size is set to 0 or
query_cache_type is set to 'OFF'
rule 'Query caching method'
[!fired('Query cache disabled')]
Questions / Uptime
value >
100
Suboptimal caching method.
You are using the MySQL Query cache with a
fairly high traffic database. It might be worth considering to use <a
href="http://dev.mysql.com/doc/refman/5.5/en/ha-memcached.html">memcached</a>
instead of the MySQL Query cache, especially if you have multiple
slaves.
The query cache is enabled and the server receives %d queries per
second. This rule fires if there is more than 100 queries per second. |
round(value,1)
rule 'Query cache efficiency (%)' [!PMA_DRIZZLE &&
Com_select + Qcache_hits > 0 && !fired('Query cache
disabled')]
Qcache_hits / (Com_select + Qcache_hits) * 100
value <
20
Query cache not running efficiently, it has a low hit rate.
Consider
increasing {query_cache_limit}.
The current query cache hit rate of %s% is
below 20% | round(value,1)
rule 'Query Cache usage' [!fired('Query cache
disabled') && !PMA_DRIZZLE]
100 - Qcache_free_memory /
query_cache_size * 100
value < 80
Less than 80% of the query cache is
being utilized.
This might be caused by {query_cache_limit} being too low.
Flushing the query cache might help as well.
The current ratio of free
query cache memory to total query cache size is %s%. It should be above 80%
| round(value,1)
rule 'Query cache fragmentation' [!fired('Query cache
disabled') && !PMA_DRIZZLE]
Qcache_free_blocks /
(Qcache_total_blocks / 2) * 100
value > 20
The query cache is
considerably fragmented.
Severe fragmentation is likely to (further)
increase Qcache_lowmem_prunes. This might be caused by many Query cache low
memory prunes due to {query_cache_size} being too small. For a immediate
but short lived fix you can flush the query cache (might lock the query
cache for a long time). Carefully adjusting {query_cache_min_res_unit} to a
lower value might help too, e.g. you can set it to the average size of your
queries in the cache using this formula: (query_cache_size -
qcache_free_memory) / qcache_queries_in_cache
The cache is currently
fragmented by %s% , with 100% fragmentation meaning that the query cache is
an alternating pattern of free and used blocks. This value should be below
20%. | round(value,1)
rule 'Query cache low memory prunes' [!PMA_DRIZZLE
&& Qcache_inserts > 0 && !fired('Query cache
disabled')]
Qcache_lowmem_prunes / Qcache_inserts * 100
value >
0.1
Cached queries are removed due to low query cache memory from the
query cache.
You might want to increase {query_cache_size}, however keep
in mind that the overhead of maintaining the cache is likely to increase
with its size, so do this in small increments and monitor the results.
The
ratio of removed queries to inserted queries is %s%. The lower this value
is, the better (This rules firing limit: 0.1%) | round(value,1)
rule
'Query cache max size' [!fired('Query cache
disabled')]
query_cache_size
value > 1024 * 128
The query cache size
is above 128 MiB. Big query caches may cause significant overhead that is
required to maintain the cache.
Depending on your environment, it might be
performance increasing to reduce this value.
Current query cache size: %s
| implode(' ',PMA_formatByteDown(value, 2, 2))
rule 'Query cache min
result size' [!fired('Query cache disabled')]
value ==
1024*1024
query_cache_limit
The max size of the result set in the query
cache is the default of 1 MiB.
Changing {query_cache_limit} (usually by
increasing) may increase efficiency. This variable determines the maximum
size a query result may have to be inserted into the query cache. If there
are many query results above 1 MiB that are well cacheable (many reads,
little writes) then increasing {query_cache_limit} will increase
efficiency. Whereas in the case of many query results being above 1 MiB
that are not very well cacheable (often invalidated due to table updates)
increasing {query_cache_limit} might reduce efficiency.
query_cache_limit
is set to 1 MiB
#
# Sorts
rule 'Percentage of sorts that cause temporary
tables' [Sort_scan + Sort_range > 0]
Sort_merge_passes / (Sort_scan +
Sort_range) * 100
value > 10
Too many sorts are causing temporary
tables.
Consider increasing sort_buffer_size and/or read_rnd_buffer_size,
depending on your system memory limits
%s% of all sorts cause temporary
tables, this value should be lower than 10%. | round(value,1)
rule 'Rate
of sorts that cause temporary tables'
Sort_merge_passes / Uptime
value *
60 * 60 > 1
Too many sorts are causing temporary tables.
Consider
increasing sort_buffer_size and/or read_rnd_buffer_size, depending on your
system memory limits
Temporary tables average: %s, this value should be
less than 1 per hour. | PMA_bytime(value,2)
rule 'Sort rows'
Sort_rows /
Uptime
value * 60 >= 1
There are lots of rows being sorted.
While
there is nothing wrong with a high amount of row sorting, you might want to
make sure that the queries which require a lot of sorting use indexed
columns in the ORDER BY clause, as this will result in much faster
sorting
Sorted rows average: %s | PMA_bytime(value,2)
# Joins, scans
rule
'Rate of joins without indexes'
(Select_range_check + Select_scan +
Select_full_join) / Uptime
value * 60 * 60 > 1
There are too many
joins without indexes.
This means that joins are doing full table scans.
Adding indexes for the columns being used in the join conditions will
greatly speed up table joins
Table joins average: %s, this value should be
less than 1 per hour | PMA_bytime(value,2)
rule 'Rate of reading first
index entry'
Handler_read_first / Uptime
value * 60 * 60 > 1
The rate
of reading the first index entry is high.
This usually indicates frequent
full index scans. Full index scans are faster than table scans but require
lots of CPU cycles in big tables, if those tables that have or had high
volumes of UPDATEs and DELETEs, running 'OPTIMIZE TABLE' might reduce the
amount of and/or speed up full index scans. Other than that full index
scans can only be reduced by rewriting queries.
Index scans average: %s,
this value should be less than 1 per hour | PMA_bytime(value,2)
rule 'Rate
of reading fixed position'
Handler_read_rnd / Uptime
value * 60 * 60 >
1
The rate of reading data from a fixed position is high.
This indicates
that many queries need to sort results and/or do a full table scan,
including join queries that do not use indexes. Add indexes where
applicable.
Rate of reading fixed position average: %s, this value should
be less than 1 per hour | PMA_bytime(value,2)
rule 'Rate of reading next
table row'
Handler_read_rnd_next / Uptime
value * 60 * 60 > 1
The
rate of reading the next table row is high.
This indicates that many
queries are doing full table scans. Add indexes where applicable.
Rate of
reading next table row: %s, this value should be less than 1 per hour |
PMA_bytime(value,2)
# temp tables
rule 'tmp_table_size vs.
max_heap_table_size'
tmp_table_size - max_heap_table_size
value
!=0
tmp_table_size and max_heap_table_size are not the same.
If you have
deliberately changed one of either: The server uses the lower value of
either to determine the maximum size of in-memory tables. So if you wish to
increase the in-memory table limit you will have to increase the other
value as well.
Current values are tmp_table_size: %s, max_heap_table_size:
%s | implode(' ',PMA_formatByteDown(tmp_table_size, 2, 2)), implode('
',PMA_formatByteDown(max_heap_table_size, 2, 2))
rule 'Percentage of temp
tables on disk' [Created_tmp_tables + Created_tmp_disk_tables >
0]
Created_tmp_disk_tables / (Created_tmp_tables +
Created_tmp_disk_tables) * 100
value > 25
Many temporary tables are
being written to disk instead of being kept in memory.
Increasing
{max_heap_table_size} and {tmp_table_size} might help. However some
temporary tables are always being written to disk, independent of the value
of these variables. To eliminate these you will have to rewrite your
queries to avoid those conditions (Within a temporary table: Presence of a
BLOB or TEXT column or presence of a column bigger than 512 bytes) as
mentioned in the beginning of an <a
href="http://www.facebook.com/note.php?note_id=10150111255065841&comments">Article
by the Pythian Group</a>
%s% of all temporary tables are being
written to disk, this value should be below 25% | round(value,1)
rule
'Temp disk rate'
Created_tmp_disk_tables / Uptime
value * 60 * 60 >
1
Many temporary tables are being written to disk instead of being kept in
memory.
Increasing {max_heap_table_size} and {tmp_table_size} might help.
However some temporary tables are always being written to disk, independent
of the value of these variables. To eliminate these you will have to
rewrite your queries to avoid those conditions (Within a temporary table:
Presence of a BLOB or TEXT column or presence of a column bigger than 512
bytes) as mentioned in the <a
href="http://dev.mysql.com/doc/refman/5.5/en/internal-temporary-tables.html">MySQL
Documentation</a>
Rate of temporary tables being written to disk:
%s, this value should be less than 1 per hour | PMA_bytime(value,2)
# I
couldn't find any source on the internet that suggests a direct relation
between high counts of temporary tables and any of these variables.
#
Several independent Blog entries suggest
(http://ronaldbradford.com/blog/more-on-understanding-sort_buffer_size-2010-05-10/
and
http://www.xaprb.com/blog/2010/05/09/how-to-tune-mysqls-sort_buffer_size/)
#
that sort_buffer_size should be left as it is. And increasing
read_buffer_size is only suggested when there are a lot of
# table scans
(http://dev.mysql.com/doc/refman/5.5/en/server-system-variables.html#sysvar_read_buffer_size
and other sources) though
# setting it too high is bad too
(http://www.mysqlperformanceblog.com/2007/09/17/mysql-what-read_buffer_size-value-is-optimal/).
#rule
'Temp table rate'
# Created_tmp_tables / Uptime
# value * 60 * 60 >
1
# Many intermediate temporary tables are being created.
# This may be
caused by queries under certain conditions as mentioned in the <a
href="http://dev.mysql.com/doc/refman/5.5/en/internal-temporary-tables.html">MySQL
Documentation</a>. Consider increasing {sort_buffer_size} (sorting),
{read_rnd_buffer_size} (random read buffer, ie, post-sort),
{read_buffer_size} (sequential scan).
#
# MyISAM index cache
rule 'MyISAM
key buffer size' [!PMA_DRIZZLE]
key_buffer_size
value == 0
Key buffer is
not initialized. No MyISAM indexes will be cached.
Set {key_buffer_size}
depending on the size of your MyISAM indexes. 64M is a good
start.
key_buffer_size is 0
rule 'Max % MyISAM key buffer ever used'
[!PMA_DRIZZLE && key_buffer_size > 0]
Key_blocks_used *
key_cache_block_size / key_buffer_size * 100
value < 95
MyISAM key
buffer (index cache) % used is low.
You may need to decrease the size of
{key_buffer_size}, re-examine your tables to see if indexes have been
removed, or examine queries and expectations about what indexes are being
used.
max % MyISAM key buffer ever used: %s%, this value should be above
95% | round(value,1)
# Don't fire if above rule fired - we don't need the
same advice twice
rule 'Percentage of MyISAM key buffer used' [!PMA_DRIZZLE
&& key_buffer_size > 0 && !fired('max % MyISAM key
buffer ever used')]
( 1 - Key_blocks_unused * key_cache_block_size /
key_buffer_size) * 100
value < 95
MyISAM key buffer (index cache) %
used is low.
You may need to decrease the size of {key_buffer_size},
re-examine your tables to see if indexes have been removed, or examine
queries and expectations about what indexes are being used.
% MyISAM key
buffer used: %s%, this value should be above 95% | round(value,1)
rule
'Percentage of index reads from memory' [!PMA_DRIZZLE &&
Key_read_requests > 0]
100 - (Key_reads / Key_read_requests *
100)
value < 95
The % of indexes that use the MyISAM key buffer is
low.
You may need to increase {key_buffer_size}.
Index reads from memory:
%s%, this value should be above 95% | round(value,1)
#
# other caches
rule
'Rate of table open' [!PMA_DRIZZLE]
Opened_tables / Uptime
value*60*60
> 10
The rate of opening tables is high.
Opening tables requires disk
I/O which is costly. Increasing {table_open_cache} might avoid
this.
Opened table rate: %s, this value should be less than 10 per hour |
PMA_bytime(value,2)
rule 'Percentage of used open files limit'
[!PMA_DRIZZLE]
Open_files / open_files_limit * 100
value > 85
The
number of open files is approaching the max number of open files. You may
get a "Too many open files" error.
Consider increasing
{open_files_limit}, and check the error log when restarting after changing
open_files_limit.
The number of opened files is at %s% of the limit. It
should be below 85% | round(value,1)
rule 'Rate of open files'
[!PMA_DRIZZLE]
Open_files / Uptime
value * 60 * 60 > 5
The rate of
opening files is high.
Consider increasing {open_files_limit}, and check
the error log when restarting after changing open_files_limit.
Opened
files rate: %s, this value should be less than 5 per hour |
PMA_bytime(value,2)
rule 'Immediate table locks %' [Table_locks_waited +
Table_locks_immediate > 0]
Table_locks_immediate / (Table_locks_waited
+ Table_locks_immediate) * 100
value < 95
Too many table locks were
not granted immediately.
Optimize queries and/or use InnoDB to reduce lock
wait.
Immediate table locks: %s%, this value should be above 95% |
round(value,1)
rule 'Table lock wait rate'
Table_locks_waited /
Uptime
value * 60 * 60 > 1
Too many table locks were not granted
immediately.
Optimize queries and/or use InnoDB to reduce lock
wait.
Table lock wait rate: %s, this value should be less than 1 per hour
| PMA_bytime(value,2)
rule 'Thread cache'
[!PMA_DRIZZLE]
thread_cache_size
value < 1
Thread cache is disabled,
resulting in more overhead from new connections to MySQL.
Enable the
thread cache by setting {thread_cache_size} > 0.
The thread cache is
set to 0
rule 'Thread cache hit rate %' [!PMA_DRIZZLE &&
thread_cache_size > 0]
100 - Threads_created / Connections
value <
80
Thread cache is not efficient.
Increase {thread_cache_size}.
Thread
cache hitrate: %s%, this value should be above 80% | round(value,1)
rule
'Threads that are slow to launch' [!PMA_DRIZZLE && slow_launch_time
> 0]
Slow_launch_threads
value > 0
There are too many threads that
are slow to launch.
This generally happens in case of general system
overload as it is pretty simple operations. You might want to monitor your
system load carefully.
%s thread(s) took longer than %s seconds to start,
it should be 0 | value, slow_launch_time
rule 'Slow launch time'
[!PMA_DRIZZLE]
slow_launch_time
value > 2
Slow_launch_threads is
above 2s
Set slow_launch_time to 1s or 2s to correctly count threads that
are slow to launch
slow_launch_time is set to %s |
value
#
#Connections
rule 'Percentage of used connections'
[!PMA_DRIZZLE]
Max_used_connections / max_connections * 100
value >
80
The maximum amount of used connections is getting close to the value of
max_connections.
Increase max_connections, or decrease wait_timeout so
that connections that do not close database handlers properly get killed
sooner. Make sure the code closes database handlers
properly.
Max_used_connections is at %s% of max_connections, it should be
below 80% | round(value,1)
rule 'Percentage of aborted
connections'
Aborted_connects / Connections * 100
value > 1
Too many
connections are aborted.
Connections are usually aborted when they cannot
be authorized. <a
href="http://www.mysqlperformanceblog.com/2008/08/23/how-to-track-down-the-source-of-aborted_connects/">This
article</a> might help you track down the source.
%s% of all
connections are aborted. This value should be below 1% |
round(value,1)
rule 'Rate of aborted connections'
Aborted_connects /
Uptime
value * 60 * 60 > 1
Too many connections are
aborted.
Connections are usually aborted when they cannot be authorized.
<a
href="http://www.mysqlperformanceblog.com/2008/08/23/how-to-track-down-the-source-of-aborted_connects/">This
article</a> might help you track down the source.
Aborted
connections rate is at %s, this value should be less than 1 per hour |
PMA_bytime(value,2)
rule 'Percentage of aborted clients'
Aborted_clients
/ Connections * 100
value > 2
Too many clients are aborted.
Clients
are usually aborted when they did not close their connection to MySQL
properly. This can be due to network issues or code not closing a database
handler properly. Check your network and code.
%s% of all clients are
aborted. This value should be below 2% | round(value,1)
rule 'Rate of
aborted clients'
Aborted_clients / Uptime
value * 60 * 60 > 1
Too
many clients are aborted.
Clients are usually aborted when they did not
close their connection to MySQL properly. This can be due to network issues
or code not closing a database handler properly. Check your network and
code.
Aborted client rate is at %s, this value should be less than 1 per
hour | PMA_bytime(value,2)
#
# InnoDB
rule 'Is InnoDB disabled?'
[!PMA_DRIZZLE]
have_innodb
value != "YES"
You do not have
InnoDB enabled.
InnoDB is usually the better choice for table
engines.
have_innodb is set to 'value'
rule 'InnoDB log size'
[innodb_buffer_pool_size > 0]
innodb_log_file_size /
innodb_buffer_pool_size * 100
value < 20
The InnoDB log file size is
not an appropriate size, in relation to the InnoDB buffer pool.
Especially
on a system with a lot of writes to InnoDB tables you should set
innodb_log_file_size to 25% of {innodb_buffer_pool_size}. However the
bigger this value, the longer the recovery time will be when database
crashes, so this value should not be set much higher than 256 MiB. Please
note however that you cannot simply change the value of this variable. You
need to shutdown the server, remove the InnoDB log files, set the new value
in my.cnf, start the server, then check the error logs if everything went
fine. See also <a
href="http://mysqldatabaseadministration.blogspot.com/2007/01/increase-innodblogfilesize-proper-way.html">this
blog entry</a>
Your InnoDB log size is at %s% in relation to the
InnoDB buffer pool size, it should not be below 20% | round(value,1)
rule
'Max InnoDB log size' [innodb_buffer_pool_size > 0 &&
innodb_log_file_size / innodb_buffer_pool_size * 100 <
30]
innodb_log_file_size / (1024 * 1024)
value >= 128
The InnoDB log
file size is inadequately large.
It is usually sufficient to set
innodb_log_file_size to 25% of the size of {innodb_buffer_pool_size}. A
very big innodb_log_file_size slows down the recovery time after a database
crash considerably. See also <a
href="http://www.mysqlperformanceblog.com/2006/07/03/choosing-proper-innodb_log_file_size/">this
Article</a>. You need to shutdown the server, remove the InnoDB log
files, set the new value in my.cnf, start the server, then check the error
logs if everything went fine. See also <a
href="http://mysqldatabaseadministration.blogspot.com/2007/01/increase-innodblogfilesize-proper-way.html">this
blog entry</a>
Your absolute InnoDB log size is %s MiB |
round(value,1)
rule 'InnoDB buffer pool size' [system_memory >
0]
innodb_buffer_pool_size / system_memory * 100
value < 60
Your
InnoDB buffer pool is fairly small.
The InnoDB buffer pool has a profound
impact on performance for InnoDB tables. Assign all your remaining memory
to this buffer. For database servers that use solely InnoDB as storage
engine and have no other services (e.g. a web server) running, you may set
this as high as 80% of your available memory. If that is not the case, you
need to carefully assess the memory consumption of your other services and
non-InnoDB-Tables and set this variable accordingly. If it is set too high,
your system will start swapping, which decreases performance significantly.
See also <a
href="http://www.mysqlperformanceblog.com/2007/11/03/choosing-innodb_buffer_pool_size/">this
article</a>
You are currently using %s% of your memory for the
InnoDB buffer pool. This rule fires if you are assigning less than 60%,
however this might be perfectly adequate for your system if you don't have
much InnoDB tables or other services running on the same machine. |
value
#
# other
rule 'MyISAM concurrent inserts'
[!PMA_DRIZZLE]
concurrent_insert
value === 0 || value === 'NEVER'
Enable
concurrent_insert by setting it to 1
Setting {concurrent_insert} to 1
reduces contention between readers and writers for a given table. See also
<a
href="http://dev.mysql.com/doc/refman/5.5/en/concurrent-inserts.html">MySQL
Documentation</a>
concurrent_insert is set to 0
# INSERT DELAYED
USAGE
#Delayed_errors 0
#Delayed_insert_threads 0
#Delayed_writes
0
#Not_flushed_delayed_rows