Mini Shell
#ifndef SQL_PARTITION_INCLUDED
#define SQL_PARTITION_INCLUDED
/* Copyright (c) 2006, 2017, Oracle and/or its affiliates.
Copyright (c) 2011, 2017, MariaDB
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_INTERFACE
#pragma interface /* gcc class implementation */
#endif
#include "sql_list.h" /* List */
#include "table.h" /* TABLE_LIST */
class Alter_info;
class Alter_table_ctx;
class Field;
class String;
class handler;
class partition_info;
struct TABLE;
struct TABLE_LIST;
typedef struct st_bitmap MY_BITMAP;
typedef struct st_key KEY;
typedef struct st_key_range key_range;
/* Flags for partition handlers */
#define HA_CAN_PARTITION (1 << 0) /* Partition support */
#define HA_CAN_UPDATE_PARTITION_KEY (1 << 1)
#define HA_CAN_PARTITION_UNIQUE (1 << 2)
#define HA_USE_AUTO_PARTITION (1 << 3)
#define HA_ONLY_VERS_PARTITION (1 << 4)
#define NORMAL_PART_NAME 0
#define TEMP_PART_NAME 1
#define RENAMED_PART_NAME 2
typedef struct st_lock_param_type
{
TABLE_LIST *table_list;
ulonglong copied;
ulonglong deleted;
THD *thd;
HA_CREATE_INFO *create_info;
Alter_info *alter_info;
Alter_table_ctx *alter_ctx;
TABLE *table;
KEY *key_info_buffer;
LEX_CUSTRING org_tabledef_version;
uchar *pack_frm_data;
uint key_count;
uint db_options;
size_t pack_frm_len;
// TODO: remove duplicate data: part_info can be accessed via table->part_info
partition_info *part_info;
} ALTER_PARTITION_PARAM_TYPE;
typedef struct {
longlong list_value;
uint32 partition_id;
} LIST_PART_ENTRY;
typedef struct {
uint32 start_part;
uint32 end_part;
} part_id_range;
class String_list;
struct st_partition_iter;
#define NOT_A_PARTITION_ID UINT_MAX32
bool is_partition_in_list(char *part_name, List<char> list_part_names);
char *are_partitions_in_table(partition_info *new_part_info,
partition_info *old_part_info);
bool check_reorganise_list(partition_info *new_part_info,
partition_info *old_part_info,
List<char> list_part_names);
handler *get_ha_partition(partition_info *part_info);
int get_part_for_buf(const uchar *buf, const uchar *rec0,
partition_info *part_info, uint32 *part_id);
void prune_partition_set(const TABLE *table, part_id_range *part_spec);
bool check_partition_info(partition_info *part_info,handlerton **eng_type,
TABLE *table, handler *file, HA_CREATE_INFO *info);
void set_linear_hash_mask(partition_info *part_info, uint num_parts);
bool fix_partition_func(THD *thd, TABLE *table, bool create_table_ind);
void get_partition_set(const TABLE *table, uchar *buf, const uint index,
const key_range *key_spec,
part_id_range *part_spec);
uint get_partition_field_store_length(Field *field);
void get_full_part_id_from_key(const TABLE *table, uchar *buf,
KEY *key_info,
const key_range *key_spec,
part_id_range *part_spec);
bool mysql_unpack_partition(THD *thd, char *part_buf,
uint part_info_len,
TABLE *table, bool is_create_table_ind,
handlerton *default_db_type,
bool *work_part_info_used);
void make_used_partitions_str(MEM_ROOT *mem_root,
partition_info *part_info, String *parts_str,
String_list &used_partitions_list);
uint32 get_list_array_idx_for_endpoint(partition_info *part_info,
bool left_endpoint,
bool include_endpoint);
uint32 get_partition_id_range_for_endpoint(partition_info *part_info,
bool left_endpoint,
bool include_endpoint);
bool check_part_func_fields(Field **ptr, bool ok_with_charsets);
bool field_is_partition_charset(Field *field);
Item* convert_charset_partition_constant(Item *item, CHARSET_INFO *cs);
/**
Append all fields in read_set to string
@param[in,out] str String to append to.
@param[in] row Row to append.
@param[in] table Table containing read_set and fields for the row.
*/
void append_row_to_str(String &str, const uchar *row, TABLE *table);
void truncate_partition_filename(char *path);
/*
A "Get next" function for partition iterator.
SYNOPSIS
partition_iter_func()
part_iter Partition iterator, you call only "iter.get_next(&iter)"
DESCRIPTION
Depending on whether partitions or sub-partitions are iterated, the
function returns next subpartition id/partition number. The sequence of
returned numbers is not ordered and may contain duplicates.
When the end of sequence is reached, NOT_A_PARTITION_ID is returned, and
the iterator resets itself (so next get_next() call will start to
enumerate the set all over again).
RETURN
NOT_A_PARTITION_ID if there are no more partitions.
[sub]partition_id of the next partition
*/
typedef uint32 (*partition_iter_func)(st_partition_iter* part_iter);
/*
Partition set iterator. Used to enumerate a set of [sub]partitions
obtained in partition interval analysis (see get_partitions_in_range_iter).
For the user, the only meaningful field is get_next, which may be used as
follows:
part_iterator.get_next(&part_iterator);
Initialization is done by any of the following calls:
- get_partitions_in_range_iter-type function call
- init_single_partition_iterator()
- init_all_partitions_iterator()
Cleanup is not needed.
*/
typedef struct st_partition_iter
{
partition_iter_func get_next;
/*
Valid for "Interval mapping" in LIST partitioning: if true, let the
iterator also produce id of the partition that contains NULL value.
*/
bool ret_null_part, ret_null_part_orig;
/*
We should return DEFAULT partition.
*/
bool ret_default_part, ret_default_part_orig;
struct st_part_num_range
{
uint32 start;
uint32 cur;
uint32 end;
};
struct st_field_value_range
{
longlong start;
longlong cur;
longlong end;
};
union
{
struct st_part_num_range part_nums;
struct st_field_value_range field_vals;
};
partition_info *part_info;
} PARTITION_ITERATOR;
/*
Get an iterator for set of partitions that match given field-space interval
SYNOPSIS
get_partitions_in_range_iter()
part_info Partitioning info
is_subpart
store_length_array Length of fields packed in opt_range_key format
min_val Left edge, field value in opt_range_key format
max_val Right edge, field value in opt_range_key format
min_len Length of minimum value
max_len Length of maximum value
flags Some combination of NEAR_MIN, NEAR_MAX, NO_MIN_RANGE,
NO_MAX_RANGE
part_iter Iterator structure to be initialized
DESCRIPTION
Functions with this signature are used to perform "Partitioning Interval
Analysis". This analysis is applicable for any type of [sub]partitioning
by some function of a single fieldX. The idea is as follows:
Given an interval "const1 <=? fieldX <=? const2", find a set of partitions
that may contain records with value of fieldX within the given interval.
The min_val, max_val and flags parameters specify the interval.
The set of partitions is returned by initializing an iterator in *part_iter
NOTES
There are currently three functions of this type:
- get_part_iter_for_interval_via_walking
- get_part_iter_for_interval_cols_via_map
- get_part_iter_for_interval_via_mapping
RETURN
0 - No matching partitions, iterator not initialized
1 - Some partitions would match, iterator intialized for traversing them
-1 - All partitions would match, iterator not initialized
*/
typedef int (*get_partitions_in_range_iter)(partition_info *part_info,
bool is_subpart,
uint32 *store_length_array,
uchar *min_val, uchar *max_val,
uint min_len, uint max_len,
uint flags,
PARTITION_ITERATOR *part_iter);
#include "partition_info.h"
#ifdef WITH_PARTITION_STORAGE_ENGINE
uint fast_alter_partition_table(THD *thd, TABLE *table,
Alter_info *alter_info,
Alter_table_ctx *alter_ctx,
HA_CREATE_INFO *create_info,
TABLE_LIST *table_list);
bool set_part_state(Alter_info *alter_info, partition_info *tab_part_info,
enum partition_state part_state);
uint prep_alter_part_table(THD *thd, TABLE *table, Alter_info *alter_info,
HA_CREATE_INFO *create_info,
bool *partition_changed,
bool *fast_alter_table);
char *generate_partition_syntax(THD *thd, partition_info *part_info,
uint *buf_length,
bool show_partition_options,
HA_CREATE_INFO *create_info,
Alter_info *alter_info);
char *generate_partition_syntax_for_frm(THD *thd, partition_info *part_info,
uint *buf_length,
HA_CREATE_INFO *create_info,
Alter_info *alter_info);
bool verify_data_with_partition(TABLE *table, TABLE *part_table,
uint32 part_id);
bool compare_partition_options(HA_CREATE_INFO *table_create_info,
partition_element *part_elem);
bool compare_table_with_partition(THD *thd, TABLE *table,
TABLE *part_table,
partition_element *part_elem,
uint part_id);
bool partition_key_modified(TABLE *table, const MY_BITMAP *fields);
bool write_log_replace_frm(ALTER_PARTITION_PARAM_TYPE *lpt,
uint next_entry,
const char *from_path,
const char *to_path);
#else
#define partition_key_modified(X,Y) 0
#endif
int __attribute__((warn_unused_result))
create_partition_name(char *out, size_t outlen, const char *in1, const char
*in2, uint name_variant, bool translate);
int __attribute__((warn_unused_result))
create_subpartition_name(char *out, size_t outlen, const char *in1, const
char *in2, const char *in3, uint name_variant);
void set_key_field_ptr(KEY *key_info, const uchar *new_buf,
const uchar *old_buf);
/** Set up table for creating a partition.
Copy info from partition to the table share so the created partition
has the correct info.
@param thd THD object
@param share Table share to be updated.
@param info Create info to be updated.
@param part_elem partition_element containing the info.
@return status
@retval TRUE Error
@retval FALSE Success
@details
Set up
1) Comment on partition
2) MAX_ROWS, MIN_ROWS on partition
3) Index file name on partition
4) Data file name on partition
*/
bool set_up_table_before_create(THD *thd,
TABLE_SHARE *share,
const char *partition_name_with_path,
HA_CREATE_INFO *info,
partition_element *part_elem);
#endif /* SQL_PARTITION_INCLUDED */
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