Subquery optimization backport:

- Factor out subquery code into sql/opt_subselect.{h,cc} - Stop using the term "confluent" (was used due to misreading the dictionary)
2025-08-07 00:04:31 +03:00 · 2010-02-16 00:53:06 +03:00
parent 4746ddf634
commit e0bb2f90a2
10 changed files with 3911 additions and 3761 deletions
--- a/.bzrignore
+++ b/.bzrignore
@@ -1922,3 +1922,7 @@ libmysqld/examples/mysqltest.cc
 extra/libevent/event-config.h
 libmysqld/opt_table_elimination.cc
 libmysqld/ha_federatedx.cc
 libmysqld/multi_range_read.cc
 libmysqld/opt_index_cond_pushdown.cc
 libmysqld/opt_subselect.cc
 libmysqld/sql_join_cache.cc
--- a/libmysqld/Makefile.am
+++ b/libmysqld/Makefile.am
@@ -58,6 +58,7 @@ sqlsources = derror.cc field.cc field_conv.cc strfunc.cc filesort.cc \
 	log_event.cc rpl_record.cc \
 	log_event_old.cc rpl_record_old.cc \
 	protocol.cc net_serv.cc opt_range.cc \
        opt_subselect.cc \
 	opt_sum.cc procedure.cc records.cc sql_acl.cc \
 	sql_load.cc discover.cc sql_locale.cc \
 	sql_profile.cc \
--- a/sql/Makefile.am
+++ b/sql/Makefile.am
@@ -60,6 +60,7 @@ noinst_HEADERS =	item.h item_func.h item_sum.h item_cmpfunc.h \
 			ha_ndbcluster_binlog.h ha_ndbcluster_tables.h \
 			ha_partition.h rpl_constants.h \
 			opt_range.h protocol.h rpl_tblmap.h rpl_utility.h \
                        opt_subselect.h \
 			rpl_reporting.h \
 			log.h log_slow.h sql_show.h rpl_rli.h rpl_mi.h \
 			sql_select.h structs.h table.h sql_udf.h hash_filo.h \
@@ -102,7 +103,8 @@ mysqld_SOURCES =	sql_lex.cc sql_handler.cc sql_partition.cc \
 			unireg.cc des_key_file.cc \
 			log_event.cc rpl_record.cc \
 			log_event_old.cc rpl_record_old.cc \
-			discover.cc time.cc opt_range.cc opt_sum.cc \
+			discover.cc time.cc opt_range.cc opt_subselect.cc \
                        opt_sum.cc \
 		   	records.cc filesort.cc handler.cc \
 		        ha_partition.cc \
 			sql_db.cc sql_table.cc sql_rename.cc sql_crypt.cc \
--- a/sql/item_subselect.cc
+++ b/sql/item_subselect.cc
@@ -31,10 +31,6 @@
 #include "mysql_priv.h"
 #include "sql_select.h"
 inline Item * and_items(Item* cond, Item *item)
 {
  return (cond? (new Item_cond_and(cond, item)) : item);
 }
 Item_subselect::Item_subselect():
  Item_result_field(), value_assigned(0), thd(0), substitution(0),
@@ -1899,7 +1895,7 @@ Item_in_subselect::select_in_like_transformer(JOIN *join, Comp_creator *func)
    object, but we can't know it here, but here we need address correct
    reference on left expresion.
-    //psergey: he means confluent cases like "... IN (SELECT 1)"
+    //psergey: he means degenerate cases like "... IN (SELECT 1)"
  */
  if (!optimizer)
  {
--- a/sql/opt_subselect.cc
+++ b/sql/opt_subselect.cc
--- a/sql/opt_subselect.h
+++ b/sql/opt_subselect.h
@@ -0,0 +1,368 @@
 /* */
 #ifdef USE_PRAGMA_INTERFACE
 #pragma interface			/* gcc class implementation */
 #endif
 int check_and_do_in_subquery_rewrites(JOIN *join);
 bool convert_join_subqueries_to_semijoins(JOIN *join);
 int pull_out_semijoin_tables(JOIN *join);
 bool optimize_semijoin_nests(JOIN *join, table_map all_table_map);
 // used by Loose_scan_opt
 ulonglong get_bound_sj_equalities(TABLE_LIST *sj_nest, 
                                  table_map remaining_tables);
 /*
  This is a class for considering possible loose index scan optimizations.
  It's usage pattern is as follows:
    best_access_path()
    {
       Loose_scan_opt opt;
       opt.init()
       for each index we can do ref access with
       {
         opt.next_ref_key();
         for each keyuse 
           opt.add_keyuse();
         opt.check_ref_access();
       }
       if (some criteria for range scans)
         opt.check_range_access();
       opt.get_best_option();
    }
 */
 class Loose_scan_opt
 {
 public:
  /* All methods must check this before doing anything else */
  bool try_loosescan;
  /*
    If we consider (oe1, .. oeN) IN (SELECT ie1, .. ieN) then ieK=oeK is
    called sj-equality. If oeK depends only on preceding tables then such
    equality is called 'bound'.
  */
  ulonglong bound_sj_equalities;
  /* Accumulated properties of ref access we're now considering: */
  ulonglong handled_sj_equalities;
  key_part_map loose_scan_keyparts;
  uint max_loose_keypart;
  bool part1_conds_met;
  /*
    Use of quick select is a special case. Some of its properties:
  */
  uint quick_uses_applicable_index;
  uint quick_max_loose_keypart;
  /* Best loose scan method so far */
  uint   best_loose_scan_key;
  double best_loose_scan_cost;
  double best_loose_scan_records;
  KEYUSE *best_loose_scan_start_key;
  uint best_max_loose_keypart;
  Loose_scan_opt():
    try_loosescan(FALSE),
    bound_sj_equalities(0),
    quick_uses_applicable_index(FALSE)
  {
    UNINIT_VAR(quick_max_loose_keypart); /* Protected by quick_uses_applicable_index */
    /* The following are protected by best_loose_scan_cost!= DBL_MAX */
    UNINIT_VAR(best_loose_scan_key);
    UNINIT_VAR(best_loose_scan_records);
    UNINIT_VAR(best_max_loose_keypart);
    UNINIT_VAR(best_loose_scan_start_key);
  }
  void init(JOIN *join, JOIN_TAB *s, table_map remaining_tables)
  {
    /*
      Discover the bound equalities. We need to do this if
        1. The next table is an SJ-inner table, and
        2. It is the first table from that semijoin, and
        3. We're not within a semi-join range (i.e. all semi-joins either have
           all or none of their tables in join_table_map), except
           s->emb_sj_nest (which we've just entered, see #2).
        4. All non-IN-equality correlation references from this sj-nest are 
           bound
        5. But some of the IN-equalities aren't (so this can't be handled by 
           FirstMatch strategy)
    */
    best_loose_scan_cost= DBL_MAX;
    if (!join->emb_sjm_nest && s->emb_sj_nest &&                        // (1)
        s->emb_sj_nest->sj_in_exprs < 64 && 
        ((remaining_tables & s->emb_sj_nest->sj_inner_tables) ==        // (2)
         s->emb_sj_nest->sj_inner_tables) &&                            // (2)
        join->cur_sj_inner_tables == 0 &&                                  // (3)
        !(remaining_tables & 
          s->emb_sj_nest->nested_join->sj_corr_tables) &&               // (4)
        remaining_tables & s->emb_sj_nest->nested_join->sj_depends_on &&// (5)
        optimizer_flag(join->thd, OPTIMIZER_SWITCH_LOOSE_SCAN))
    {
      /* This table is an LooseScan scan candidate */
      bound_sj_equalities= get_bound_sj_equalities(s->emb_sj_nest, 
                                                   remaining_tables);
      try_loosescan= TRUE;
      DBUG_PRINT("info", ("Will try LooseScan scan, bound_map=%llx",
                          (longlong)bound_sj_equalities));
    }
  }
  void next_ref_key()
  {
    handled_sj_equalities=0;
    loose_scan_keyparts= 0;
    max_loose_keypart= 0;
    part1_conds_met= FALSE;
  }
  void add_keyuse(table_map remaining_tables, KEYUSE *keyuse)
  {
    if (try_loosescan && keyuse->sj_pred_no != UINT_MAX)
    {
      if (!(remaining_tables & keyuse->used_tables))
      {
        /* 
          This allows to use equality propagation to infer that some 
          sj-equalities are bound.
        */
        bound_sj_equalities |= 1ULL << keyuse->sj_pred_no;
      }
      else
      {
        handled_sj_equalities |= 1ULL << keyuse->sj_pred_no;
        loose_scan_keyparts |= ((key_part_map)1) << keyuse->keypart;
        set_if_bigger(max_loose_keypart, keyuse->keypart);
      }
    }
  }
  bool have_a_case() { return test(handled_sj_equalities); }
  void check_ref_access_part1(JOIN_TAB *s, uint key, KEYUSE *start_key, 
                              table_map found_part)
  {
    /*
      Check if we can use LooseScan semi-join strategy. We can if
      1. This is the right table at right location
      2. All IN-equalities are either
         - "bound", ie. the outer_expr part refers to the preceding tables
         - "handled", ie. covered by the index we're considering
      3. Index order allows to enumerate subquery's duplicate groups in
         order. This happens when the index definition matches this
         pattern:
           (handled_col|bound_col)* (other_col|bound_col)
    */
    if (try_loosescan &&                                       // (1)
        (handled_sj_equalities | bound_sj_equalities) ==         // (2)
        PREV_BITS(ulonglong, s->emb_sj_nest->sj_in_exprs) &&     // (2)
        (PREV_BITS(key_part_map, max_loose_keypart+1) &        // (3)
         (found_part | loose_scan_keyparts)) ==                // (3)
         (found_part | loose_scan_keyparts) &&                 // (3)
        !key_uses_partial_cols(s->table, key))
    {
      /* Ok, can use the strategy */
      part1_conds_met= TRUE;
      if (s->quick && s->quick->index == key && 
          s->quick->get_type() == QUICK_SELECT_I::QS_TYPE_RANGE)
      {
        quick_uses_applicable_index= TRUE;
        quick_max_loose_keypart= max_loose_keypart;
      }
      DBUG_PRINT("info", ("Can use LooseScan scan"));
      /* 
        Check if this is a special case where there are no usable bound
        IN-equalities, i.e. we have
          outer_expr IN (SELECT innertbl.key FROM ...) 
        and outer_expr cannot be evaluated yet, so it's actually full
        index scan and not a ref access
      */
      if (!(found_part & 1 ) && /* no usable ref access for 1st key part */
          s->table->covering_keys.is_set(key))
      {
        DBUG_PRINT("info", ("Can use full index scan for LooseScan"));
        /* Calculate the cost of complete loose index scan.  */
        double records= rows2double(s->table->file->stats.records);
        /* The cost is entire index scan cost (divided by 2) */
        double read_time= s->table->file->index_only_read_time(key, records);
        /*
          Now find out how many different keys we will get (for now we
          ignore the fact that we have "keypart_i=const" restriction for
          some key components, that may make us think think that loose
          scan will produce more distinct records than it actually will)
        */
        ulong rpc;
        if ((rpc= s->table->key_info[key].rec_per_key[max_loose_keypart]))
          records= records / rpc;
        // TODO: previous version also did /2
        if (read_time < best_loose_scan_cost)
        {
          best_loose_scan_key= key;
          best_loose_scan_cost= read_time;
          best_loose_scan_records= records;
          best_max_loose_keypart= max_loose_keypart;
          best_loose_scan_start_key= start_key;
        }
      }
    }
  }
  void check_ref_access_part2(uint key, KEYUSE *start_key, double records, 
                              double read_time)
  {
    if (part1_conds_met && read_time < best_loose_scan_cost)
    {
      /* TODO use rec-per-key-based fanout calculations */
      best_loose_scan_key= key;
      best_loose_scan_cost= read_time;
      best_loose_scan_records= records;
      best_max_loose_keypart= max_loose_keypart;
      best_loose_scan_start_key= start_key;
    }
  }
  void check_range_access(JOIN *join, uint idx, QUICK_SELECT_I *quick)
  {
    /* TODO: this the right part restriction: */
    if (quick_uses_applicable_index && idx == join->const_tables && 
        quick->read_time < best_loose_scan_cost)
    {
      best_loose_scan_key= quick->index;
      best_loose_scan_cost= quick->read_time;
      /* this is ok because idx == join->const_tables */
      best_loose_scan_records= rows2double(quick->records);
      best_max_loose_keypart= quick_max_loose_keypart;
      best_loose_scan_start_key= NULL;
    }
  }
  void save_to_position(JOIN_TAB *tab, POSITION *pos)
  {
    pos->read_time=       best_loose_scan_cost;
    if (best_loose_scan_cost != DBL_MAX)
    {
      pos->records_read=    best_loose_scan_records;
      pos->key=             best_loose_scan_start_key;
      pos->loosescan_key=   best_loose_scan_key;
      pos->loosescan_parts= best_max_loose_keypart + 1;
      pos->use_join_buffer= FALSE;
      pos->table=           tab;
      // todo need ref_depend_map ?
      DBUG_PRINT("info", ("Produced a LooseScan plan, key %s, %s",
                          tab->table->key_info[best_loose_scan_key].name,
                          best_loose_scan_start_key? "(ref access)":
                                                     "(range/index access)"));
    }
  }
 };
 void advance_sj_state(JOIN *join, const table_map remaining_tables, 
                      const JOIN_TAB *new_join_tab, uint idx, 
                      double *current_record_count, double *current_read_time,
                      POSITION *loose_scan_pos);
 void restore_prev_sj_state(const table_map remaining_tables, 
                                  const JOIN_TAB *tab, uint idx);
 void fix_semijoin_strategies_for_picked_join_order(JOIN *join);
 bool setup_sj_materialization(JOIN_TAB *tab);
 TABLE *create_duplicate_weedout_tmp_table(THD *thd, uint uniq_tuple_length_arg,
                                          SJ_TMP_TABLE *sjtbl);
 int do_sj_reset(SJ_TMP_TABLE *sj_tbl);
 int do_sj_dups_weedout(THD *thd, SJ_TMP_TABLE *sjtbl);
 /*
  Temporary table used by semi-join DuplicateElimination strategy
  This consists of the temptable itself and data needed to put records
  into it. The table's DDL is as follows:
    CREATE TABLE tmptable (col VARCHAR(n) BINARY, PRIMARY KEY(col));
  where the primary key can be replaced with unique constraint if n exceeds
  the limit (as it is always done for query execution-time temptables).
  The record value is a concatenation of rowids of tables from the join we're
  executing. If a join table is on the inner side of the outer join, we
  assume that its rowid can be NULL and provide means to store this rowid in
  the tuple.
 */
 class SJ_TMP_TABLE : public Sql_alloc
 {
 public:
  /*
    Array of pointers to tables whose rowids compose the temporary table
    record.
  */
  class TAB
  {
  public:
    JOIN_TAB *join_tab;
    uint rowid_offset;
    ushort null_byte;
    uchar null_bit;
  };
  TAB *tabs;
  TAB *tabs_end;
  /* 
    is_degenerate==TRUE means this is a special case where the temptable record
    has zero length (and presence of a unique key means that the temptable can
    have either 0 or 1 records). 
    In this case we don't create the physical temptable but instead record
    its state in SJ_TMP_TABLE::have_degenerate_row.
  */
  bool is_degenerate;
  /* 
    When is_degenerate==TRUE: the contents of the table (whether it has the
    record or not).
  */
  bool have_degenerate_row;
  /* table record parameters */
  uint null_bits;
  uint null_bytes;
  uint rowid_len;
  /* The temporary table itself (NULL means not created yet) */
  TABLE *tmp_table;
  /*
    These are the members we got from temptable creation code. We'll need
    them if we'll need to convert table from HEAP to MyISAM/Maria.
  */
  ENGINE_COLUMNDEF *start_recinfo;
  ENGINE_COLUMNDEF *recinfo;
  /* Pointer to next table (next->start_idx > this->end_idx) */
  SJ_TMP_TABLE *next; 
 };
 int setup_semijoin_dups_elimination(JOIN *join, ulonglong options, 
                                    uint no_jbuf_after);
 void destroy_sj_tmp_tables(JOIN *join);
 int clear_sj_tmp_tables(JOIN *join);
 int rewrite_to_index_subquery_engine(JOIN *join);
--- a/sql/sql_join_cache.cc
+++ b/sql/sql_join_cache.cc
@@ -29,6 +29,7 @@
 #include "mysql_priv.h"
 #include "sql_select.h"
 #include "opt_subselect.h"
 /*****************************************************************************
--- a/sql/sql_lex.h
+++ b/sql/sql_lex.h
@@ -605,7 +605,7 @@ public:
  List<TABLE_LIST> top_join_list; /* join list of the top level          */
  List<TABLE_LIST> *join_list;    /* list for the currently parsed join  */
  TABLE_LIST *embedding;          /* table embedding to the above list   */
-  List<TABLE_LIST> sj_nests;
+  List<TABLE_LIST> sj_nests;      /* Semi-join nests within this join */
  /*
    Beginning of the list of leaves in a FROM clause, where the leaves
    inlcude all base tables including view tables. The tables are connected
--- a/sql/sql_select.cc
+++ b/sql/sql_select.cc
--- a/sql/sql_select.h
+++ b/sql/sql_select.h
@@ -28,6 +28,12 @@
 #include "procedure.h"
 #include <myisam.h>
 #if defined(WITH_MARIA_STORAGE_ENGINE) && defined(USE_MARIA_FOR_TMP_TABLES)
 #include "../storage/maria/ha_maria.h"
 #define TMP_ENGINE_HTON maria_hton
 #else
 #define TMP_ENGINE_HTON myisam_hton
 #endif
 /* Values in optimize */
 #define KEY_OPTIMIZE_EXISTS		1
 #define KEY_OPTIMIZE_REF_OR_NULL	2
@@ -1195,7 +1201,6 @@ enum_nested_loop_state sub_select(JOIN *join,JOIN_TAB *join_tab, bool
                                  end_of_records);
 enum_nested_loop_state sub_select_sjm(JOIN *join, JOIN_TAB *join_tab, 
                                      bool end_of_records);
 int do_sj_dups_weedout(THD *thd, SJ_TMP_TABLE *sjtbl);
 enum_nested_loop_state
 end_send_group(JOIN *join, JOIN_TAB *join_tab __attribute__((unused)),
@@ -1329,74 +1334,6 @@ typedef struct st_rollup
  List<Item> *fields;
 } ROLLUP;
 /*
  Temporary table used by semi-join DuplicateElimination strategy
  This consists of the temptable itself and data needed to put records
  into it. The table's DDL is as follows:
    CREATE TABLE tmptable (col VARCHAR(n) BINARY, PRIMARY KEY(col));
  where the primary key can be replaced with unique constraint if n exceeds
  the limit (as it is always done for query execution-time temptables).
  The record value is a concatenation of rowids of tables from the join we're
  executing. If a join table is on the inner side of the outer join, we
  assume that its rowid can be NULL and provide means to store this rowid in
  the tuple.
 */
 class SJ_TMP_TABLE : public Sql_alloc
 {
 public:
  /*
    Array of pointers to tables whose rowids compose the temporary table
    record.
  */
  class TAB
  {
  public:
    JOIN_TAB *join_tab;
    uint rowid_offset;
    ushort null_byte;
    uchar null_bit;
  };
  TAB *tabs;
  TAB *tabs_end;
  /* 
    is_confluent==TRUE means this is a special case where the temptable record
    has zero length (and presence of a unique key means that the temptable can
    have either 0 or 1 records). 
    In this case we don't create the physical temptable but instead record
    its state in SJ_TMP_TABLE::have_confluent_record.
  */
  bool is_confluent;
  /* 
    When is_confluent==TRUE: the contents of the table (whether it has the
    record or not).
  */
  bool have_confluent_row;
  /* table record parameters */
  uint null_bits;
  uint null_bytes;
  uint rowid_len;
  /* The temporary table itself (NULL means not created yet) */
  TABLE *tmp_table;
  /*
    These are the members we got from temptable creation code. We'll need
    them if we'll need to convert table from HEAP to MyISAM/Maria.
  */
  ENGINE_COLUMNDEF *start_recinfo;
  ENGINE_COLUMNDEF *recinfo;
  /* Pointer to next table (next->start_idx > this->end_idx) */
  SJ_TMP_TABLE *next; 
 };
 #define SJ_OPT_NONE 0
 #define SJ_OPT_DUPS_WEEDOUT 1
@@ -1711,7 +1648,6 @@ public:
 			  Item_sum ***func);
  int rollup_send_data(uint idx);
  int rollup_write_data(uint idx, TABLE *table);
  void remove_subq_pushed_predicates(Item **where);
  /**
    Release memory and, if possible, the open tables held by this execution
    plan (and nested plans). It's used to release some tables before
@@ -1763,11 +1699,6 @@ void TEST_join(JOIN *join);
 /* Extern functions in sql_select.cc */
 bool store_val_in_field(Field *field, Item *val, enum_check_fields check_flag);
 TABLE *create_tmp_table(THD *thd,TMP_TABLE_PARAM *param,List<Item> &fields,
 			ORDER *group, bool distinct, bool save_sum_fields,
 			ulonglong select_options, ha_rows rows_limit,
 			char* alias);
 void free_tmp_table(THD *thd, TABLE *entry);
 void count_field_types(SELECT_LEX *select_lex, TMP_TABLE_PARAM *param, 
                       List<Item> &fields, bool reset_with_sum_func);
 bool setup_copy_fields(THD *thd, TMP_TABLE_PARAM *param,
@@ -1776,10 +1707,6 @@ bool setup_copy_fields(THD *thd, TMP_TABLE_PARAM *param,
 		       uint elements, List<Item> &fields);
 void copy_fields(TMP_TABLE_PARAM *param);
 void copy_funcs(Item **func_ptr);
 bool create_internal_tmp_table_from_heap(THD *thd, TABLE *table,
                                         ENGINE_COLUMNDEF *start_recinfo,
                                         ENGINE_COLUMNDEF **recinfo, 
                                         int error, bool ignore_last_dupp_key_error);
 uint find_shortest_key(TABLE *table, const key_map *usable_keys);
 Field* create_tmp_field_from_field(THD *thd, Field* org_field,
                                   const char *name, TABLE *table,
@@ -1955,13 +1882,59 @@ int test_if_item_cache_changed(List<Cached_item> &list);
 void calc_used_field_length(THD *thd, JOIN_TAB *join_tab);
 int join_init_read_record(JOIN_TAB *tab);
 void set_position(JOIN *join,uint idx,JOIN_TAB *table,KEYUSE *key);
 inline Item * and_items(Item* cond, Item *item)
 {
  return (cond? (new Item_cond_and(cond, item)) : item);
 }
 bool choose_plan(JOIN *join,table_map join_tables);
 void get_partial_join_cost(JOIN *join, uint n_tables, double *read_time_arg,
                           double *record_count_arg);
 void optimize_wo_join_buffering(JOIN *join, uint first_tab, uint last_tab, 
                                table_map last_remaining_tables, 
                                bool first_alt, uint no_jbuf_before,
                                double *reopt_rec_count, double *reopt_cost,
                                double *sj_inner_fanout);
 Item_equal *find_item_equal(COND_EQUAL *cond_equal, Field *field,
                            bool *inherited_fl);
 bool test_if_ref(COND *root_cond, 
                 Item_field *left_item,Item *right_item);
 inline bool optimizer_flag(THD *thd, uint flag)
 { 
  return (thd->variables.optimizer_switch & flag);
 }
 /* Table elimination entry point function */
 void eliminate_tables(JOIN *join);
 /* Index Condition Pushdown entry point function */
 void push_index_cond(JOIN_TAB *tab, uint keyno, bool other_tbls_ok);
 /****************************************************************************
  Temporary table support for SQL Runtime
 ***************************************************************************/
 #define STRING_TOTAL_LENGTH_TO_PACK_ROWS 128
 #define AVG_STRING_LENGTH_TO_PACK_ROWS   64
 #define RATIO_TO_PACK_ROWS	       2
 #define MIN_STRING_LENGTH_TO_PACK_ROWS   10
 TABLE *create_tmp_table(THD *thd,TMP_TABLE_PARAM *param,List<Item> &fields,
 			ORDER *group, bool distinct, bool save_sum_fields,
 			ulonglong select_options, ha_rows rows_limit,
 			char* alias);
 void free_tmp_table(THD *thd, TABLE *entry);
 bool create_internal_tmp_table_from_heap(THD *thd, TABLE *table,
                                         ENGINE_COLUMNDEF *start_recinfo,
                                         ENGINE_COLUMNDEF **recinfo, 
                                         int error, bool ignore_last_dupp_key_error);
 bool create_internal_tmp_table(TABLE *table, KEY *keyinfo, 
                               ENGINE_COLUMNDEF *start_recinfo,
                               ENGINE_COLUMNDEF **recinfo, 
                               ulonglong options);
 bool open_tmp_table(TABLE *table);
 void setup_tmp_table_column_bitmaps(TABLE *table, uchar *bitmaps);