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mariadb/storage/heap/ha_heap.cc
Monty b66cdbd1ea Changing all cost calculation to be given in milliseconds 
This makes it easier to compare different costs and also allows
the optimizer to optimizer different storage engines more reliably.

- Added tests/check_costs.pl, a tool to verify optimizer cost calculations.
  - Most engine costs has been found with this program. All steps to
    calculate the new costs are documented in Docs/optimizer_costs.txt

- User optimizer_cost variables are given in microseconds (as individual
  costs can be very small). Internally they are stored in ms.
- Changed DISK_READ_COST (was DISK_SEEK_BASE_COST) from a hard disk cost
  (9 ms) to common SSD cost (400MB/sec).
- Removed cost calculations for hard disks (rotation etc).
- Changed the following handler functions to return IO_AND_CPU_COST.
  This makes it easy to apply different cost modifiers in ha_..time()
  functions for io and cpu costs.
  - scan_time()
  - rnd_pos_time() & rnd_pos_call_time()
  - keyread_time()
- Enhanched keyread_time() to calculate the full cost of reading of a set
  of keys with a given number of ranges and optional number of blocks that
  need to be accessed.
- Removed read_time() as keyread_time() + rnd_pos_time() can do the same
  thing and more.
- Tuned cost for: heap, myisam, Aria, InnoDB, archive and MyRocks.
  Used heap table costs for json_table. The rest are using default engine
  costs.
- Added the following new optimizer variables:
  - optimizer_disk_read_ratio
  - optimizer_disk_read_cost
  - optimizer_key_lookup_cost
  - optimizer_row_lookup_cost
  - optimizer_row_next_find_cost
  - optimizer_scan_cost
- Moved all engine specific cost to OPTIMIZER_COSTS structure.
- Changed costs to use 'records_out' instead of 'records_read' when
  recalculating costs.
- Split optimizer_costs.h to optimizer_costs.h and optimizer_defaults.h.
  This allows one to change costs without having to compile a lot of
  files.
- Updated costs for filter lookup.
- Use a better cost estimate in best_extension_by_limited_search()
  for the sorting cost.
- Fixed previous issues with 'filtered' explain column as we are now
  using 'records_out' (min rows seen for table) to calculate filtering.
  This greatly simplifies the filtering code in
  JOIN_TAB::save_explain_data().

This change caused a lot of queries to be optimized differently than
before, which exposed different issues in the optimizer that needs to
be fixed.  These fixes are in the following commits.  To not have to
change the same test case over and over again, the changes in the test
cases are done in a single commit after all the critical change sets
are done.

InnoDB changes:
- Updated InnoDB to not divide big range cost with 2.
- Added cost for InnoDB (innobase_update_optimizer_costs()).
- Don't mark clustered primary key with HA_KEYREAD_ONLY. This will
  prevent that the optimizer is trying to use index-only scans on
  the clustered key.
- Disabled ha_innobase::scan_time() and ha_innobase::read_time() and
  ha_innobase::rnd_pos_time() as the default engine cost functions now
  works good for InnoDB.

Other things:
- Added  --show-query-costs (\Q) option to mysql.cc to show the query
  cost after each query (good when working with query costs).
- Extended my_getopt with GET_ADJUSTED_VALUE which allows one to adjust
  the value that user is given. This is used to change cost from
  microseconds (user input) to milliseconds (what the server is
  internally using).
- Added include/my_tracker.h  ; Useful include file to quickly test
  costs of a function.
- Use handler::set_table() in all places instead of 'table= arg'.
- Added SHOW_OPTIMIZER_COSTS to sys variables. These are input and
  shown in microseconds for the user but stored as milliseconds.
  This is to make the numbers easier to read for the user (less
  pre-zeros).  Implemented in 'Sys_var_optimizer_cost' class.
- In test_quick_select() do not use index scans if 'no_keyread' is set
  for the table. This is what we do in other places of the server.
- Added THD parameter to Unique::get_use_cost() and
  check_index_intersect_extension() and similar functions to be able
  to provide costs to called functions.
- Changed 'records' to 'rows' in optimizer_trace.
- Write more information to optimizer_trace.
- Added INDEX_BLOCK_FILL_FACTOR_MUL (4) and INDEX_BLOCK_FILL_FACTOR_DIV (3)
  to calculate usage space of keys in b-trees. (Before we used numeric
  constants).
- Removed code that assumed that b-trees has similar costs as binary
  trees. Replaced with engine calls that returns the cost.
- Added Bitmap::find_first_bit()
- Added timings to join_cache for ANALYZE table (patch by Sergei Petrunia).
- Added records_init and records_after_filter to POSITION to remember
  more of what best_access_patch() calculates.
- table_after_join_selectivity() changed to recalculate 'records_out'
  based on the new fields from best_access_patch()

Bug fixes:
- Some queries did not update last_query_cost (was 0). Fixed by moving
  setting thd->...last_query_cost in JOIN::optimize().
- Write '0' as number of rows for const tables with a matching row.

Some internals:
- Engine cost are stored in OPTIMIZER_COSTS structure.  When a
  handlerton is created, we also created a new cost variable for the
  handlerton. We also create a new variable if the user changes a
  optimizer cost for a not yet loaded handlerton either with command
  line arguments or with SET
  @@global.engine.optimizer_cost_variable=xx.
- There are 3 global OPTIMIZER_COSTS variables:
  default_optimizer_costs   The default costs + changes from the
                            command line without an engine specifier.
  heap_optimizer_costs      Heap table costs, used for temporary tables
  tmp_table_optimizer_costs The cost for the default on disk internal
                            temporary table (MyISAM or Aria)
- The engine cost for a table is stored in table_share. To speed up
  accesses the handler has a pointer to this. The cost is copied
  to the table on first access. If one wants to change the cost one
  must first update the global engine cost and then do a FLUSH TABLES.
  This was done to be able to access the costs for an open table
  without any locks.
- When a handlerton is created, the cost are updated the following way:
  See sql/keycaches.cc for details:
  - Use 'default_optimizer_costs' as a base
  - Call hton->update_optimizer_costs() to override with the engines
    default costs.
  - Override the costs that the user has specified for the engine.
  - One handler open, copy the engine cost from handlerton to TABLE_SHARE.
  - Call handler::update_optimizer_costs() to allow the engine to update
    cost for this particular table.
  - There are two costs stored in THD. These are copied to the handler
    when the table is used in a query:
    - optimizer_where_cost
    - optimizer_scan_setup_cost
- Simply code in best_access_path() by storing all cost result in a
  structure. (Idea/Suggestion by Igor)
2023-02-02 23:54:45 +03:00

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/*
Copyright (c) 2000, 2011, Oracle and/or its affiliates
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1335 USA */
#ifdef USE_PRAGMA_IMPLEMENTATION
#pragma implementation // gcc: Class implementation
#endif
#define MYSQL_SERVER 1
#include "heapdef.h"
#include "sql_priv.h"
#include "sql_plugin.h"
#include "ha_heap.h"
#include "sql_base.h"
static handler *heap_create_handler(handlerton *, TABLE_SHARE *, MEM_ROOT *);
static int heap_prepare_hp_create_info(TABLE *, bool, HP_CREATE_INFO *);
static int heap_panic(handlerton *hton, ha_panic_function flag)
{
return hp_panic(flag);
}
static int heap_drop_table(handlerton *hton, const char *path)
{
int error= heap_delete_table(path);
return error == ENOENT ? -1 : error;
}
/* See optimizer_costs.txt for how the following values where calculated */
#define HEAP_ROW_NEXT_FIND_COST 8.0166e-06 // For table scan
#define BTREE_KEY_NEXT_FIND_COST 0.00007739 // For binary tree scan
#define HEAP_LOOKUP_COST 0.00016097 // Heap lookup cost
static void heap_update_optimizer_costs(OPTIMIZER_COSTS *costs)
{
/*
A lot of values are 0 as heap supports all needed xxx_time() functions
*/
costs->disk_read_cost=0; // All data in memory
costs->disk_read_ratio= 0.0; // All data in memory
costs->key_next_find_cost= 0;
costs->key_copy_cost= 0; // Set in keyread_time()
costs->row_copy_cost= 2.334e-06; // This is small as its just a memcpy
costs->row_lookup_cost= 0; // Direct pointer
costs->row_next_find_cost= 0;
costs->key_lookup_cost= 0;
costs->key_next_find_cost= 0;
costs->index_block_copy_cost= 0;
}
int heap_init(void *p)
{
handlerton *heap_hton;
init_heap_psi_keys();
heap_hton= (handlerton *)p;
heap_hton->db_type= DB_TYPE_HEAP;
heap_hton->create= heap_create_handler;
heap_hton->panic= heap_panic;
heap_hton->drop_table= heap_drop_table;
heap_hton->update_optimizer_costs= heap_update_optimizer_costs;
heap_hton->flags= HTON_CAN_RECREATE;
return 0;
}
static handler *heap_create_handler(handlerton *hton,
TABLE_SHARE *table,
MEM_ROOT *mem_root)
{
return new (mem_root) ha_heap(hton, table);
}
/*****************************************************************************
** HEAP tables
*****************************************************************************/
ha_heap::ha_heap(handlerton *hton, TABLE_SHARE *table_arg)
:handler(hton, table_arg), file(0), records_changed(0), key_stat_version(0),
internal_table(0)
{
}
/*
Hash index statistics is updated (copied from HP_KEYDEF::hash_buckets to
rec_per_key) after 1/HEAP_STATS_UPDATE_THRESHOLD fraction of table records
have been inserted/updated/deleted. delete_all_rows() and table flush cause
immediate update.
NOTE
hash index statistics must be updated when number of table records changes
from 0 to non-zero value and vice versa. Otherwise records_in_range may
erroneously return 0 and 'range' may miss records.
*/
#define HEAP_STATS_UPDATE_THRESHOLD 10
int ha_heap::open(const char *name, int mode, uint test_if_locked)
{
internal_table= MY_TEST(test_if_locked & HA_OPEN_INTERNAL_TABLE);
if (internal_table || (!(file= heap_open(name, mode)) && my_errno == ENOENT))
{
HP_CREATE_INFO create_info;
my_bool created_new_share;
int rc;
file= 0;
if (heap_prepare_hp_create_info(table, internal_table, &create_info))
goto end;
create_info.pin_share= TRUE;
rc= heap_create(name, &create_info, &internal_share, &created_new_share);
my_free(create_info.keydef);
if (rc)
goto end;
implicit_emptied= MY_TEST(created_new_share);
if (internal_table)
file= heap_open_from_share(internal_share, mode);
else
file= heap_open_from_share_and_register(internal_share, mode);
if (!file)
{
heap_release_share(internal_share, internal_table);
goto end;
}
}
ref_length= sizeof(HEAP_PTR);
/* Initialize variables for the opened table */
set_keys_for_scanning();
/*
We cannot run update_key_stats() here because we do not have a
lock on the table. The 'records' count might just be changed
temporarily at this moment and we might get wrong statistics (Bug
#10178). Instead we request for update. This will be done in
ha_heap::info(), which is always called before key statistics are
used.
*/
key_stat_version= file->s->key_stat_version-1;
end:
return (file ? 0 : 1);
}
int ha_heap::close(void)
{
return internal_table ? hp_close(file) : heap_close(file);
}
/*
Create a copy of this table
DESCRIPTION
Do same as default implementation but use file->s->name instead of
table->s->path. This is needed by Windows where the clone() call sees
'/'-delimited path in table->s->path, while ha_heap::open() was called
with '\'-delimited path.
*/
handler *ha_heap::clone(const char *name, MEM_ROOT *mem_root)
{
handler *new_handler= get_new_handler(table->s, mem_root, ht);
if (new_handler && !new_handler->ha_open(table, file->s->name, table->db_stat,
HA_OPEN_IGNORE_IF_LOCKED))
return new_handler;
return NULL; /* purecov: inspected */
}
/*
Compute which keys to use for scanning
SYNOPSIS
set_keys_for_scanning()
no parameter
DESCRIPTION
Set the bitmap btree_keys, which is used when the upper layers ask
which keys to use for scanning. For each btree index the
corresponding bit is set.
RETURN
void
*/
void ha_heap::set_keys_for_scanning(void)
{
btree_keys.clear_all();
for (uint i= 0 ; i < table->s->keys ; i++)
{
if (table->key_info[i].algorithm == HA_KEY_ALG_BTREE)
btree_keys.set_bit(i);
}
}
int ha_heap::can_continue_handler_scan()
{
int error= 0;
if ((file->key_version != file->s->key_version && inited == INDEX) ||
(file->file_version != file->s->file_version && inited == RND))
{
/* Data changed, not safe to do index or rnd scan */
error= HA_ERR_RECORD_CHANGED;
}
return error;
}
void ha_heap::update_key_stats()
{
for (uint i= 0; i < table->s->keys; i++)
{
KEY *key=table->key_info+i;
if (!key->rec_per_key)
continue;
if (key->algorithm != HA_KEY_ALG_BTREE)
{
if (key->flags & HA_NOSAME)
key->rec_per_key[key->user_defined_key_parts-1]= 1;
else
{
ha_rows hash_buckets= file->s->keydef[i].hash_buckets;
ulong no_records= hash_buckets ? (ulong)(file->s->records/hash_buckets) : 2;
if (no_records < 2)
no_records= 2;
key->rec_per_key[key->user_defined_key_parts-1]= no_records;
}
}
}
records_changed= 0;
/* At the end of update_key_stats() we can proudly claim they are OK. */
key_stat_version= file->s->key_stat_version;
}
IO_AND_CPU_COST ha_heap::keyread_time(uint index, ulong ranges, ha_rows rows,
ulonglong blocks)
{
KEY *key=table->key_info+index;
if (key->algorithm == HA_KEY_ALG_BTREE)
{
double lookup_cost;
lookup_cost= ranges * costs->key_cmp_cost * log2(stats.records+1);
return {0, ranges * lookup_cost + (rows-ranges) * BTREE_KEY_NEXT_FIND_COST };
}
else
{
return {0, (ranges * HEAP_LOOKUP_COST +
(rows-ranges) * BTREE_KEY_NEXT_FIND_COST) };
}
}
IO_AND_CPU_COST ha_heap::scan_time()
{
return {0, (double) (stats.records+stats.deleted) * HEAP_ROW_NEXT_FIND_COST };
}
IO_AND_CPU_COST ha_heap::rnd_pos_time(ha_rows rows)
{
/*
The row pointer is a direct pointer to the block. Thus almost instant
in practice.
Note that ha_rnd_pos_time() will add ROW_COPY_COST to this result
*/
return { 0, 0 };
}
int ha_heap::write_row(const uchar * buf)
{
int res;
if (table->next_number_field && buf == table->record[0])
{
if ((res= update_auto_increment()))
return res;
}
res= heap_write(file,buf);
if (!res && (++records_changed*HEAP_STATS_UPDATE_THRESHOLD >
file->s->records))
{
/*
We can perform this safely since only one writer at the time is
allowed on the table.
*/
records_changed= 0;
file->s->key_stat_version++;
}
return res;
}
int ha_heap::update_row(const uchar * old_data, const uchar * new_data)
{
int res;
res= heap_update(file,old_data,new_data);
if (!res && ++records_changed*HEAP_STATS_UPDATE_THRESHOLD >
file->s->records)
{
/*
We can perform this safely since only one writer at the time is
allowed on the table.
*/
records_changed= 0;
file->s->key_stat_version++;
}
return res;
}
int ha_heap::delete_row(const uchar * buf)
{
int res;
res= heap_delete(file,buf);
if (!res && table->s->tmp_table == NO_TMP_TABLE &&
++records_changed*HEAP_STATS_UPDATE_THRESHOLD > file->s->records)
{
/*
We can perform this safely since only one writer at the time is
allowed on the table.
*/
records_changed= 0;
file->s->key_stat_version++;
}
return res;
}
int ha_heap::index_read_map(uchar *buf, const uchar *key,
key_part_map keypart_map,
enum ha_rkey_function find_flag)
{
DBUG_ASSERT(inited==INDEX);
int error = heap_rkey(file,buf,active_index, key, keypart_map, find_flag);
return error;
}
int ha_heap::index_read_last_map(uchar *buf, const uchar *key,
key_part_map keypart_map)
{
DBUG_ASSERT(inited==INDEX);
int error= heap_rkey(file, buf, active_index, key, keypart_map,
HA_READ_PREFIX_LAST);
return error;
}
int ha_heap::index_read_idx_map(uchar *buf, uint index, const uchar *key,
key_part_map keypart_map,
enum ha_rkey_function find_flag)
{
int error = heap_rkey(file, buf, index, key, keypart_map, find_flag);
return error;
}
int ha_heap::index_next(uchar * buf)
{
DBUG_ASSERT(inited==INDEX);
int error=heap_rnext(file,buf);
return error;
}
int ha_heap::index_prev(uchar * buf)
{
DBUG_ASSERT(inited==INDEX);
int error=heap_rprev(file,buf);
return error;
}
int ha_heap::index_first(uchar * buf)
{
DBUG_ASSERT(inited==INDEX);
int error=heap_rfirst(file, buf, active_index);
return error;
}
int ha_heap::index_last(uchar * buf)
{
DBUG_ASSERT(inited==INDEX);
int error=heap_rlast(file, buf, active_index);
return error;
}
int ha_heap::rnd_init(bool scan)
{
return scan ? heap_scan_init(file) : 0;
}
int ha_heap::rnd_next(uchar *buf)
{
int error=heap_scan(file, buf);
return error;
}
int ha_heap::rnd_pos(uchar * buf, uchar *pos)
{
int error;
HEAP_PTR heap_position;
memcpy(&heap_position, pos, sizeof(HEAP_PTR));
error=heap_rrnd(file, buf, heap_position);
return error;
}
void ha_heap::position(const uchar *record)
{
*(HEAP_PTR*) ref= heap_position(file); // Ref is aligned
}
int ha_heap::info(uint flag)
{
HEAPINFO hp_info;
(void) heap_info(file,&hp_info,flag);
errkey= hp_info.errkey;
stats.records= hp_info.records;
stats.deleted= hp_info.deleted;
stats.mean_rec_length= hp_info.reclength;
stats.data_file_length= hp_info.data_length;
stats.index_file_length= hp_info.index_length;
stats.max_data_file_length= hp_info.max_records * hp_info.reclength;
stats.delete_length= hp_info.deleted * hp_info.reclength;
stats.create_time= (ulong) hp_info.create_time;
if (flag & HA_STATUS_AUTO)
stats.auto_increment_value= hp_info.auto_increment;
/*
If info() is called for the first time after open(), we will still
have to update the key statistics. Hoping that a table lock is now
in place.
*/
if (key_stat_version != file->s->key_stat_version)
update_key_stats();
return 0;
}
int ha_heap::extra(enum ha_extra_function operation)
{
return heap_extra(file,operation);
}
int ha_heap::reset()
{
return heap_reset(file);
}
int ha_heap::delete_all_rows()
{
heap_clear(file);
if (table->s->tmp_table == NO_TMP_TABLE)
{
/*
We can perform this safely since only one writer at the time is
allowed on the table.
*/
file->s->key_stat_version++;
}
return 0;
}
int ha_heap::reset_auto_increment(ulonglong value)
{
file->s->auto_increment= value;
return 0;
}
int ha_heap::external_lock(THD *thd, int lock_type)
{
#if !defined(DBUG_OFF) && defined(EXTRA_DEBUG)
if (lock_type == F_UNLCK && file->s->changed && heap_check_heap(file, 0))
return HA_ERR_CRASHED;
#endif
return 0; // No external locking
}
/*
Disable indexes.
SYNOPSIS
disable_indexes()
mode mode of operation:
HA_KEY_SWITCH_NONUNIQ disable all non-unique keys
HA_KEY_SWITCH_ALL disable all keys
HA_KEY_SWITCH_NONUNIQ_SAVE dis. non-uni. and make persistent
HA_KEY_SWITCH_ALL_SAVE dis. all keys and make persistent
DESCRIPTION
Disable indexes and clear keys to use for scanning.
IMPLEMENTATION
HA_KEY_SWITCH_NONUNIQ is not implemented.
HA_KEY_SWITCH_NONUNIQ_SAVE is not implemented with HEAP.
HA_KEY_SWITCH_ALL_SAVE is not implemented with HEAP.
RETURN
0 ok
HA_ERR_WRONG_COMMAND mode not implemented.
*/
int ha_heap::disable_indexes(uint mode)
{
int error;
if (mode == HA_KEY_SWITCH_ALL)
{
if (!(error= heap_disable_indexes(file)))
set_keys_for_scanning();
}
else
{
/* mode not implemented */
error= HA_ERR_WRONG_COMMAND;
}
return error;
}
/*
Enable indexes.
SYNOPSIS
enable_indexes()
mode mode of operation:
HA_KEY_SWITCH_NONUNIQ enable all non-unique keys
HA_KEY_SWITCH_ALL enable all keys
HA_KEY_SWITCH_NONUNIQ_SAVE en. non-uni. and make persistent
HA_KEY_SWITCH_ALL_SAVE en. all keys and make persistent
DESCRIPTION
Enable indexes and set keys to use for scanning.
The indexes might have been disabled by disable_index() before.
The function works only if both data and indexes are empty,
since the heap storage engine cannot repair the indexes.
To be sure, call handler::delete_all_rows() before.
IMPLEMENTATION
HA_KEY_SWITCH_NONUNIQ is not implemented.
HA_KEY_SWITCH_NONUNIQ_SAVE is not implemented with HEAP.
HA_KEY_SWITCH_ALL_SAVE is not implemented with HEAP.
RETURN
0 ok
HA_ERR_CRASHED data or index is non-empty. Delete all rows and retry.
HA_ERR_WRONG_COMMAND mode not implemented.
*/
int ha_heap::enable_indexes(uint mode)
{
int error;
if (mode == HA_KEY_SWITCH_ALL)
{
if (!(error= heap_enable_indexes(file)))
set_keys_for_scanning();
}
else
{
/* mode not implemented */
error= HA_ERR_WRONG_COMMAND;
}
return error;
}
/*
Test if indexes are disabled.
SYNOPSIS
indexes_are_disabled()
no parameters
RETURN
0 indexes are not disabled
1 all indexes are disabled
[2 non-unique indexes are disabled - NOT YET IMPLEMENTED]
*/
int ha_heap::indexes_are_disabled(void)
{
return heap_indexes_are_disabled(file);
}
THR_LOCK_DATA **ha_heap::store_lock(THD *thd,
THR_LOCK_DATA **to,
enum thr_lock_type lock_type)
{
if (lock_type != TL_IGNORE && file->lock.type == TL_UNLOCK)
file->lock.type=lock_type;
*to++= &file->lock;
return to;
}
/*
We have to ignore ENOENT entries as the HEAP table is created on open and
not when doing a CREATE on the table.
*/
int ha_heap::delete_table(const char *name)
{
return heap_drop_table(0, name);
}
void ha_heap::drop_table(const char *name)
{
file->s->delete_on_close= 1;
ha_close();
}
int ha_heap::rename_table(const char * from, const char * to)
{
return heap_rename(from,to);
}
ha_rows ha_heap::records_in_range(uint inx, const key_range *min_key,
const key_range *max_key, page_range *pages)
{
KEY *key=table->key_info+inx;
if (key->algorithm == HA_KEY_ALG_BTREE)
return hp_rb_records_in_range(file, inx, min_key, max_key);
if (!min_key || !max_key ||
min_key->length != max_key->length ||
min_key->length != key->key_length ||
min_key->flag != HA_READ_KEY_EXACT ||
max_key->flag != HA_READ_AFTER_KEY)
return HA_POS_ERROR; // Can only use exact keys
if (stats.records <= 1)
return stats.records;
/* Assert that info() did run. We need current statistics here. */
DBUG_ASSERT(key_stat_version == file->s->key_stat_version);
return key->rec_per_key[key->user_defined_key_parts-1];
}
static int heap_prepare_hp_create_info(TABLE *table_arg, bool internal_table,
HP_CREATE_INFO *hp_create_info)
{
TABLE_SHARE *share= table_arg->s;
uint key, parts, mem_per_row= 0, keys= share->keys;
uint auto_key= 0, auto_key_type= 0;
ha_rows max_rows;
HP_KEYDEF *keydef;
HA_KEYSEG *seg;
bool found_real_auto_increment= 0;
bzero(hp_create_info, sizeof(*hp_create_info));
for (key= parts= 0; key < keys; key++)
parts+= table_arg->key_info[key].user_defined_key_parts;
if (!my_multi_malloc(hp_key_memory_HP_KEYDEF,
MYF(MY_WME | MY_THREAD_SPECIFIC),
&keydef, keys * sizeof(HP_KEYDEF),
&seg, parts * sizeof(HA_KEYSEG),
NULL))
return my_errno;
for (key= 0; key < keys; key++)
{
KEY *pos= table_arg->key_info+key;
KEY_PART_INFO *key_part= pos->key_part;
KEY_PART_INFO *key_part_end= key_part + pos->user_defined_key_parts;
keydef[key].keysegs= (uint) pos->user_defined_key_parts;
keydef[key].flag= (pos->flags & (HA_NOSAME | HA_NULL_ARE_EQUAL));
keydef[key].seg= seg;
switch (pos->algorithm) {
case HA_KEY_ALG_UNDEF:
case HA_KEY_ALG_HASH:
keydef[key].algorithm= HA_KEY_ALG_HASH;
mem_per_row+= sizeof(char*) * 2; // = sizeof(HASH_INFO)
break;
case HA_KEY_ALG_BTREE:
keydef[key].algorithm= HA_KEY_ALG_BTREE;
mem_per_row+=sizeof(TREE_ELEMENT)+pos->key_length+sizeof(char*);
break;
default:
DBUG_ASSERT(0); // cannot happen
}
for (; key_part != key_part_end; key_part++, seg++)
{
Field *field= key_part->field;
if (pos->algorithm == HA_KEY_ALG_BTREE)
seg->type= field->key_type();
else
{
if ((seg->type = field->key_type()) != (int) HA_KEYTYPE_TEXT &&
seg->type != HA_KEYTYPE_VARTEXT1 &&
seg->type != HA_KEYTYPE_VARTEXT2 &&
seg->type != HA_KEYTYPE_VARBINARY1 &&
seg->type != HA_KEYTYPE_VARBINARY2 &&
seg->type != HA_KEYTYPE_BIT)
seg->type= HA_KEYTYPE_BINARY;
}
seg->start= (uint) key_part->offset;
seg->length= (uint) key_part->length;
seg->flag= key_part->key_part_flag;
if (field->flags & (ENUM_FLAG | SET_FLAG))
seg->charset= &my_charset_bin;
else
seg->charset= field->charset_for_protocol();
if (field->null_ptr)
{
seg->null_bit= field->null_bit;
seg->null_pos= (uint) (field->null_ptr - (uchar*) table_arg->record[0]);
}
else
{
seg->null_bit= 0;
seg->null_pos= 0;
}
if (field->flags & AUTO_INCREMENT_FLAG &&
table_arg->found_next_number_field &&
key == share->next_number_index)
{
/*
Store key number and type for found auto_increment key
We have to store type as seg->type can differ from it
*/
auto_key= key+ 1;
auto_key_type= field->key_type();
}
if (seg->type == HA_KEYTYPE_BIT)
{
seg->bit_length= ((Field_bit *) field)->bit_len;
seg->bit_start= ((Field_bit *) field)->bit_ofs;
seg->bit_pos= (uint) (((Field_bit *) field)->bit_ptr -
(uchar*) table_arg->record[0]);
}
else
{
seg->bit_length= seg->bit_start= 0;
seg->bit_pos= 0;
}
}
}
mem_per_row+= MY_ALIGN(MY_MAX(share->reclength, sizeof(char*)) + 1, sizeof(char*));
if (table_arg->found_next_number_field)
{
keydef[share->next_number_index].flag|= HA_AUTO_KEY;
found_real_auto_increment= share->next_number_key_offset == 0;
}
hp_create_info->auto_key= auto_key;
hp_create_info->auto_key_type= auto_key_type;
hp_create_info->max_table_size=current_thd->variables.max_heap_table_size;
hp_create_info->with_auto_increment= found_real_auto_increment;
hp_create_info->internal_table= internal_table;
max_rows= (ha_rows) (hp_create_info->max_table_size / mem_per_row);
if (share->max_rows && share->max_rows < max_rows)
max_rows= share->max_rows;
hp_create_info->max_records= (ulong) MY_MIN(max_rows, ULONG_MAX);
hp_create_info->min_records= (ulong) MY_MIN(share->min_rows, ULONG_MAX);
hp_create_info->keys= share->keys;
hp_create_info->reclength= share->reclength;
hp_create_info->keydef= keydef;
return 0;
}
int ha_heap::create(const char *name, TABLE *table_arg,
HA_CREATE_INFO *create_info)
{
int error;
my_bool created;
HP_CREATE_INFO hp_create_info;
error= heap_prepare_hp_create_info(table_arg, internal_table,
&hp_create_info);
if (error)
return error;
hp_create_info.auto_increment= (create_info->auto_increment_value ?
create_info->auto_increment_value - 1 : 0);
error= heap_create(name, &hp_create_info, &internal_share, &created);
my_free(hp_create_info.keydef);
DBUG_ASSERT(file == 0);
return (error);
}
void ha_heap::update_create_info(HA_CREATE_INFO *create_info)
{
table->file->info(HA_STATUS_AUTO);
if (!(create_info->used_fields & HA_CREATE_USED_AUTO))
create_info->auto_increment_value= stats.auto_increment_value;
}
void ha_heap::get_auto_increment(ulonglong offset, ulonglong increment,
ulonglong nb_desired_values,
ulonglong *first_value,
ulonglong *nb_reserved_values)
{
ha_heap::info(HA_STATUS_AUTO);
*first_value= stats.auto_increment_value;
/* such table has only table-level locking so reserves up to +inf */
*nb_reserved_values= ULONGLONG_MAX;
}
bool ha_heap::check_if_incompatible_data(HA_CREATE_INFO *info,
uint table_changes)
{
/* Check that auto_increment value was not changed */
if ((info->used_fields & HA_CREATE_USED_AUTO &&
info->auto_increment_value != 0) ||
table_changes == IS_EQUAL_NO ||
table_changes & IS_EQUAL_PACK_LENGTH) // Not implemented yet
return COMPATIBLE_DATA_NO;
return COMPATIBLE_DATA_YES;
}
/**
Find record by unique index (used in temporary tables with the index)
@param record (IN|OUT) the record to find
@param unique_idx (IN) number of index (for this engine)
@note It is like hp_search but uses function for raw where hp_search
uses functions for index.
@retval 0 OK
@retval 1 Not found
@retval -1 Error
*/
int ha_heap::find_unique_row(uchar *record, uint unique_idx)
{
DBUG_ENTER("ha_heap::find_unique_row");
HP_SHARE *share= file->s;
DBUG_ASSERT(inited==NONE);
HP_KEYDEF *keyinfo= share->keydef + unique_idx;
DBUG_ASSERT(keyinfo->algorithm == HA_KEY_ALG_HASH);
DBUG_ASSERT(keyinfo->flag & HA_NOSAME);
if (!share->records)
DBUG_RETURN(1); // not found
HASH_INFO *pos= hp_find_hash(&keyinfo->block,
hp_mask(hp_rec_hashnr(keyinfo, record),
share->blength, share->records));
do
{
if (!hp_rec_key_cmp(keyinfo, pos->ptr_to_rec, record))
{
file->current_hash_ptr= pos;
file->current_ptr= pos->ptr_to_rec;
file->update = HA_STATE_AKTIV;
/*
We compare it only by record in the index, so better to read all
records.
*/
memcpy(record, file->current_ptr, (size_t) share->reclength);
DBUG_RETURN(0); // found and position set
}
}
while ((pos= pos->next_key));
DBUG_RETURN(1); // not found
}
struct st_mysql_storage_engine heap_storage_engine=
{ MYSQL_HANDLERTON_INTERFACE_VERSION };
maria_declare_plugin(heap)
{
MYSQL_STORAGE_ENGINE_PLUGIN,
&heap_storage_engine,
"MEMORY",
"MySQL AB",
"Hash based, stored in memory, useful for temporary tables",
PLUGIN_LICENSE_GPL,
heap_init,
NULL,
0x0100, /* 1.0 */
NULL, /* status variables */
NULL, /* system variables */
"1.0", /* string version */
MariaDB_PLUGIN_MATURITY_STABLE /* maturity */
}
maria_declare_plugin_end;
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