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26.12.17.10 Memory Summary Tables

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The Performance Schema instruments memory usage and aggregates memory usage statistics, detailed by these factors:

  • Type of memory used (various caches, internal buffers, and so forth)

  • Thread, account, user, host indirectly performing the memory operation

The Performance Schema instruments the following aspects of memory use

  • Memory sizes used

  • Operation counts

  • Low and high water marks

Memory sizes help to understand or tune the memory consumption of the server.

Operation counts help to understand or tune the overall pressure the server is putting on the memory allocator, which has an impact on performance. Allocating a single byte one million times is not the same as allocating one million bytes a single time; tracking both sizes and counts can expose the difference.

Low and high water marks are critical to detect workload spikes, overall workload stability, and possible memory leaks.

Memory summary tables do not contain timing information because memory events are not timed.

For information about collecting memory usage data, see Memory Instrumentation Behavior.

Example memory event summary information:

  1. mysql> SELECT *
  2.        FROM performance_schema.memory_summary_global_by_event_name
  3.        WHERE EVENT_NAME = 'memory/sql/TABLE'\G
  4. *************************** 1. row ***************************
  5.                   EVENT_NAME: memory/sql/TABLE
  6.                  COUNT_ALLOC: 1381
  7.                   COUNT_FREE: 924
  8.    SUM_NUMBER_OF_BYTES_ALLOC: 2059873
  9.     SUM_NUMBER_OF_BYTES_FREE: 1407432
  10.               LOW_COUNT_USED: 0
  11.           CURRENT_COUNT_USED: 457
  12.              HIGH_COUNT_USED: 461
  13.     LOW_NUMBER_OF_BYTES_USED: 0
  14. CURRENT_NUMBER_OF_BYTES_USED: 652441
  15.    HIGH_NUMBER_OF_BYTES_USED: 669269

Each memory summary table has one or more grouping columns to indicate how the table aggregates events. Event names refer to names of event instruments in the setup_instruments table:

Each memory summary table has these summary columns containing aggregated values:

  • COUNT_ALLOC, COUNT_FREE

    The aggregated numbers of calls to memory-allocation and memory-free functions.

  • SUM_NUMBER_OF_BYTES_ALLOC, SUM_NUMBER_OF_BYTES_FREE

    The aggregated sizes of allocated and freed memory blocks.

  • CURRENT_COUNT_USED

    The aggregated number of currently allocated blocks that have not been freed yet. This is a convenience column, equal to COUNT_ALLOCCOUNT_FREE.

  • CURRENT_NUMBER_OF_BYTES_USED

    The aggregated size of currently allocated memory blocks that have not been freed yet. This is a convenience column, equal to SUM_NUMBER_OF_BYTES_ALLOCSUM_NUMBER_OF_BYTES_FREE.

  • LOW_COUNT_USED, HIGH_COUNT_USED

    The low and high water marks corresponding to the CURRENT_COUNT_USED column.

  • LOW_NUMBER_OF_BYTES_USED, HIGH_NUMBER_OF_BYTES_USED

    The low and high water marks corresponding to the CURRENT_NUMBER_OF_BYTES_USED column.

The memory summary tables have these indexes:

TRUNCATE TABLE is permitted for memory summary tables. It has these effects:

  • In general, truncation resets the baseline for statistics, but does not change the server state. That is, truncating a memory table does not free memory.

  • COUNT_ALLOC and COUNT_FREE are reset to a new baseline, by reducing each counter by the same value.

  • Likewise, SUM_NUMBER_OF_BYTES_ALLOC and SUM_NUMBER_OF_BYTES_FREE are reset to a new baseline.

  • LOW_COUNT_USED and HIGH_COUNT_USED are reset to CURRENT_COUNT_USED.

  • LOW_NUMBER_OF_BYTES_USED and HIGH_NUMBER_OF_BYTES_USED are reset to CURRENT_NUMBER_OF_BYTES_USED.

In addition, each memory summary table that is aggregated by account, host, user, or thread is implicitly truncated by truncation of the connection table on which it depends, or truncation of memory_summary_global_by_event_name. For details, see Section 26.12.8, “Performance Schema Connection Tables”.

Memory Instrumentation Behavior

Memory instruments are listed in the setup_instruments table and have names of the form memory/code_area/instrument_name. Memory instrumentation is enabled by default.

Instruments named with the prefix memory/performance_schema/ expose how much memory is allocated for internal buffers in the Performance Schema itself. The memory/performance_schema/ instruments are built in, always enabled, and cannot be disabled at startup or runtime. Built-in memory instruments are displayed only in the memory_summary_global_by_event_name table.

To control memory instrumentation state at server startup, use lines like these in your my.cnf file:

  • Enable: 

    [mysqld]
performance-schema-instrument='memory/%=ON'

  • Disable: 

    [mysqld]
performance-schema-instrument='memory/%=OFF'

To control memory instrumentation state at runtime, update the ENABLED column of the relevant instruments in the setup_instruments table:

  • Enable:

    1. UPDATE performance_schema.setup_instruments
    2. SET ENABLED = 'YES'
    3. WHERE NAME LIKE 'memory/%';

  • Disable:

    1. UPDATE performance_schema.setup_instruments
    2. SET ENABLED = 'NO'
    3. WHERE NAME LIKE 'memory/%';

For memory instruments, the TIMED column in setup_instruments is ignored because memory operations are not timed.

When a thread in the server executes a memory allocation that has been instrumented, these rules apply:

  • If the thread is not instrumented or the memory instrument is not enabled, the memory block allocated is not instrumented.

  • Otherwise (that is, both the thread and the instrument are enabled), the memory block allocated is instrumented.

For deallocation, these rules apply:

  • If a memory allocation operation was instrumented, the corresponding free operation is instrumented, regardless of the current instrument or thread enabled status.

  • If a memory allocation operation was not instrumented, the corresponding free operation is not instrumented, regardless of the current instrument or thread enabled status.

For the per-thread statistics, the following rules apply.

When an instrumented memory block of size N is allocated, the Performance Schema makes these updates to memory summary table columns:

  • COUNT_ALLOC: Increased by 1

  • CURRENT_COUNT_USED: Increased by 1

  • HIGH_COUNT_USED: Increased if CURRENT_COUNT_USED is a new maximum

  • SUM_NUMBER_OF_BYTES_ALLOC: Increased by N

  • CURRENT_NUMBER_OF_BYTES_USED: Increased by N

  • HIGH_NUMBER_OF_BYTES_USED: Increased if CURRENT_NUMBER_OF_BYTES_USED is a new maximum

When an instrumented memory block is deallocated, the Performance Schema makes these updates to memory summary table columns:

  • COUNT_FREE: Increased by 1

  • CURRENT_COUNT_USED: Decreased by 1

  • LOW_COUNT_USED: Decreased if CURRENT_COUNT_USED is a new minimum

  • SUM_NUMBER_OF_BYTES_FREE: Increased by N

  • CURRENT_NUMBER_OF_BYTES_USED: Decreased by N

  • LOW_NUMBER_OF_BYTES_USED: Decreased if CURRENT_NUMBER_OF_BYTES_USED is a new minimum

For higher-level aggregates (global, by account, by user, by host), the same rules apply as expected for low and high water marks.

  • LOW_COUNT_USED and LOW_NUMBER_OF_BYTES_USED are lower estimates. The value reported by the Performance Schema is guaranteed to be less than or equal to the lowest count or size of memory effectively used at runtime.

  • HIGH_COUNT_USED and HIGH_NUMBER_OF_BYTES_USED are higher estimates. The value reported by the Performance Schema is guaranteed to be greater than or equal to the highest count or size of memory effectively used at runtime.

For lower estimates in summary tables other than memory_summary_global_by_event_name, it is possible for values to go negative if memory ownership is transferred between threads.

Here is an example of estimate computation; but note that estimate implementation is subject to change:

Thread 1 uses memory in the range from 1MB to 2MB during execution, as reported by the LOW_NUMBER_OF_BYTES_USED and HIGH_NUMBER_OF_BYTES_USED columns of the memory_summary_by_thread_by_event_name table.

Thread 2 uses memory in the range from 10MB to 12MB during execution, as reported likewise.

When these two threads belong to the same user account, the per-account summary estimates that this account used memory in the range from 11MB to 14MB. That is, the LOW_NUMBER_OF_BYTES_USED for the higher level aggregate is the sum of each LOW_NUMBER_OF_BYTES_USED (assuming the worst case). Likewise, the HIGH_NUMBER_OF_BYTES_USED for the higher level aggregate is the sum of each HIGH_NUMBER_OF_BYTES_USED (assuming the worst case).

11MB is a lower estimate that can occur only if both threads hit the low usage mark at the same time.

14MB is a higher estimate that can occur only if both threads hit the high usage mark at the same time.

The real memory usage for this account could have been in the range from 11.5MB to 13.5MB.

For capacity planning, reporting the worst case is actually the desired behavior, as it shows what can potentially happen when sessions are uncorrelated, which is typically the case.


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