/* Copyright (C) 2000-2006 MySQL AB 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ /** @file @brief join cache optimizations @defgroup Query_Optimizer Query Optimizer @{ */ #ifdef USE_PRAGMA_IMPLEMENTATION #pragma implementation // gcc: Class implementation #endif #include "key.h" #include "sql_base.h" #include "sql_select.h" #include "opt_subselect.h" #define NO_MORE_RECORDS_IN_BUFFER (uint)(-1) static void save_or_restore_used_tabs(JOIN_TAB *join_tab, bool save); /***************************************************************************** * Join cache module ******************************************************************************/ /* Fill in the descriptor of a flag field associated with a join cache SYNOPSIS add_field_flag_to_join_cache() str position in a record buffer to copy the field from/to length length of the field field IN/OUT pointer to the field descriptor to fill in DESCRIPTION The function fill in the descriptor of a cache flag field to which the parameter 'field' points to. The function uses the first two parameters to set the position in the record buffer from/to which the field value is to be copied and the length of the copied fragment. Before returning the result the function increments the value of *field by 1. The function ignores the fields 'blob_length' and 'ofset' of the descriptor. RETURN VALUE the length of the field */ static uint add_flag_field_to_join_cache(uchar *str, uint length, CACHE_FIELD **field) { CACHE_FIELD *copy= *field; copy->str= str; copy->length= length; copy->type= 0; copy->field= 0; copy->referenced_field_no= 0; (*field)++; return length; } /* Fill in the descriptors of table data fields associated with a join cache SYNOPSIS add_table_data_fields_to_join_cache() tab descriptors of fields from this table are to be filled field_set descriptors for only these fields are to be created field_cnt IN/OUT counter of data fields descr IN/OUT pointer to the first descriptor to be filled field_ptr_cnt IN/OUT counter of pointers to the data fields descr_ptr IN/OUT pointer to the first pointer to blob descriptors DESCRIPTION The function fills in the descriptors of cache data fields from the table 'tab'. The descriptors are filled only for the fields marked in the bitmap 'field_set'. The function fills the descriptors starting from the position pointed by 'descr'. If an added field is of a BLOB type then a pointer to the its descriptor is added to the array descr_ptr. At the return 'descr' points to the position after the last added descriptor while 'descr_ptr' points to the position right after the last added pointer. RETURN VALUE the total length of the added fields */ static uint add_table_data_fields_to_join_cache(JOIN_TAB *tab, MY_BITMAP *field_set, uint *field_cnt, CACHE_FIELD **descr, uint *field_ptr_cnt, CACHE_FIELD ***descr_ptr) { Field **fld_ptr; uint len= 0; CACHE_FIELD *copy= *descr; CACHE_FIELD **copy_ptr= *descr_ptr; uint used_fields= bitmap_bits_set(field_set); for (fld_ptr= tab->table->field; used_fields; fld_ptr++) { if (bitmap_is_set(field_set, (*fld_ptr)->field_index)) { len+= (*fld_ptr)->fill_cache_field(copy); if (copy->type == CACHE_BLOB) { *copy_ptr= copy; copy_ptr++; (*field_ptr_cnt)++; } copy->field= *fld_ptr; copy->referenced_field_no= 0; copy++; (*field_cnt)++; used_fields--; } } *descr= copy; *descr_ptr= copy_ptr; return len; } /* Determine different counters of fields associated with a record in the cache SYNOPSIS calc_record_fields() DESCRIPTION The function counts the number of total fields stored in a record of the cache and saves this number in the 'fields' member. It also determines the number of flag fields and the number of blobs. The function sets 'with_match_flag' on if 'join_tab' needs a match flag i.e. if it is the first inner table of an outer join or a semi-join. RETURN VALUE none */ void JOIN_CACHE::calc_record_fields() { JOIN_TAB *tab; if (prev_cache) tab= prev_cache->join_tab; else { if (join_tab->bush_root_tab) { /* --ot1--SJM1--------------ot2--... | | +-it1--...--itN ^____________ this->join_tab is somewhere here, inside an sjm nest. The join buffer should store the values of it1.*, it2.*, .. It should not store values of ot1.*. */ tab= join_tab->bush_root_tab->bush_children->start; } else { /* -ot1--ot2--SJM1--SJM2--------------ot3--...--otN | | ^ | +-it21--...--it2N | | \-- we're somewhere here, +-it11--...--it1N at the top level The join buffer should store the values of ot1.*, ot2.*, it1{i}, it2{j}.*, ot3.*, ... that is, we should start from the first non-const top-level table. We will need to store columns of SJ-inner tables (it_X_Y.*), but we're not interested in storing the columns of materialization tables themselves. Beause of that, if the first non-const top-level table is a materialized table, we move to its bush_children: */ tab= join->join_tab + join->const_tables; if (tab->bush_children) tab= tab->bush_children->start; } } DBUG_ASSERT(!tab->bush_children); start_tab= tab; fields= 0; blobs= 0; flag_fields= 0; data_field_count= 0; data_field_ptr_count= 0; referenced_fields= 0; /* The following loop will get inside SJM nests, because data may be unpacked to sjm-inner tables. */ for (; tab != join_tab ; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { tab->calc_used_field_length(FALSE); flag_fields+= test(tab->used_null_fields || tab->used_uneven_bit_fields); flag_fields+= test(tab->table->maybe_null); fields+= tab->used_fields; blobs+= tab->used_blobs; } if ((with_match_flag= join_tab->use_match_flag())) flag_fields++; fields+= flag_fields; } /* Collect information on join key arguments SYNOPSIS collect_info_on_key_args() DESCRIPTION The function traverses the ref expressions that are used to access the joined table join_tab. For each table 'tab' whose fields are to be stored in the join buffer of the cache the function finds the fields from 'tab' that occur in the ref expressions and marks these fields in the bitmap tab->table->tmp_set. The function counts the number of them stored in this cache and the total number of them stored in the previous caches and saves the results of the counting in 'local_key_arg_fields' and 'external_key_arg_fields' respectively. NOTES The function does not do anything if no key is used to join the records from join_tab. RETURN VALUE none */ void JOIN_CACHE::collect_info_on_key_args() { JOIN_TAB *tab; JOIN_CACHE *cache; local_key_arg_fields= 0; external_key_arg_fields= 0; if (!is_key_access()) return; TABLE_REF *ref= &join_tab->ref; cache= this; do { for (tab= cache->start_tab; tab != cache->join_tab; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { uint key_args; bitmap_clear_all(&tab->table->tmp_set); for (uint i= 0; i < ref->key_parts; i++) { Item *ref_item= ref->items[i]; if (!(tab->table->map & ref_item->used_tables())) continue; ref_item->walk(&Item::add_field_to_set_processor, 1, (uchar *) tab->table); } if ((key_args= bitmap_bits_set(&tab->table->tmp_set))) { if (cache == this) local_key_arg_fields+= key_args; else external_key_arg_fields+= key_args; } } cache= cache->prev_cache; } while (cache); return; } /* Allocate memory for descriptors and pointers to them associated with the cache SYNOPSIS alloc_fields() DESCRIPTION The function allocates memory for the array of fields descriptors and the array of pointers to the field descriptors used to copy join record data from record buffers into the join buffer and backward. Some pointers refer to the field descriptor associated with previous caches. They are placed at the beginning of the array of pointers and its total number is stored in external_key_arg_fields. The pointer of the first array is assigned to field_descr and the number of the elements in it is precalculated by the function calc_record_fields. The allocated arrays are adjacent. NOTES The memory is allocated in join->thd->memroot RETURN VALUE pointer to the first array */ int JOIN_CACHE::alloc_fields() { uint ptr_cnt= external_key_arg_fields+blobs+1; uint fields_size= sizeof(CACHE_FIELD)*fields; field_descr= (CACHE_FIELD*) sql_alloc(fields_size + sizeof(CACHE_FIELD*)*ptr_cnt); blob_ptr= (CACHE_FIELD **) ((uchar *) field_descr + fields_size); return (field_descr == NULL); } /* Create descriptors of the record flag fields stored in the join buffer SYNOPSIS create_flag_fields() DESCRIPTION The function creates descriptors of the record flag fields stored in the join buffer. These are descriptors for: - an optional match flag field, - table null bitmap fields, - table null row fields. The match flag field is created when 'join_tab' is the first inner table of an outer join our a semi-join. A null bitmap field is created for any table whose fields are to be stored in the join buffer if at least one of these fields is nullable or is a BIT field whose bits are partially stored with null bits. A null row flag is created for any table assigned to the cache if it is an inner table of an outer join. The descriptor for flag fields are placed one after another at the beginning of the array of field descriptors 'field_descr' that contains 'fields' elements. If there is a match flag field the descriptor for it is always first in the sequence of flag fields. The descriptors for other flag fields can follow in an arbitrary order. The flag field values follow in a record stored in the join buffer in the same order as field descriptors, with the match flag always following first. The function sets the value of 'flag_fields' to the total number of the descriptors created for the flag fields. The function sets the value of 'length' to the total length of the flag fields. RETURN VALUE none */ void JOIN_CACHE::create_flag_fields() { CACHE_FIELD *copy; JOIN_TAB *tab; copy= field_descr; length=0; /* If there is a match flag the first field is always used for this flag */ if (with_match_flag) length+= add_flag_field_to_join_cache((uchar*) &join_tab->found, sizeof(join_tab->found), ©); /* Create fields for all null bitmaps and null row flags that are needed */ for (tab= start_tab; tab != join_tab; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { TABLE *table= tab->table; /* Create a field for the null bitmap from table if needed */ if (tab->used_null_fields || tab->used_uneven_bit_fields) length+= add_flag_field_to_join_cache(table->null_flags, table->s->null_bytes, ©); /* Create table for the null row flag if needed */ if (table->maybe_null) length+= add_flag_field_to_join_cache((uchar*) &table->null_row, sizeof(table->null_row), ©); } /* Theoretically the new value of flag_fields can be less than the old one */ flag_fields= copy-field_descr; } /* Create descriptors of the fields used to build access keys to the joined table SYNOPSIS create_key_arg_fields() DESCRIPTION The function creates descriptors of the record fields stored in the join buffer that are used to build access keys to the joined table. These fields are put into the buffer ahead of other records fields stored in the buffer. Such placement helps to optimize construction of access keys. For each field that is used to build access keys to the joined table but is stored in some other join cache buffer the function saves a pointer to the the field descriptor. The array of such pointers are placed in the the join cache structure just before the array of pointers to the blob fields blob_ptr. Any field stored in a join cache buffer that is used to construct keys to access tables associated with other join caches is called a referenced field. It receives a unique number that is saved by the function in the member 'referenced_field_no' of the CACHE_FIELD descriptor for the field. This number is used as index to the array of offsets to the referenced fields that are saved and put in the join cache buffer after all record fields. The function also finds out whether that the keys to access join_tab can be considered as embedded and, if so, sets the flag 'use_emb_key' in this join cache appropriately. NOTES. When a key to access the joined table 'join_tab' is constructed the array of pointers to the field descriptors for the external fields is looked through. For each of this pointers we find out in what previous key cache the referenced field is stored. The value of 'referenced_field_no' provides us with the index into the array of offsets for referenced fields stored in the join cache. The offset read by the the index allows us to read the field without reading all other fields of the record stored the join cache buffer. This optimizes the construction of keys to access 'join_tab' when some key arguments are stored in the previous join caches. NOTES The function does not do anything if no key is used to join the records from join_tab. RETURN VALUE none */ void JOIN_CACHE::create_key_arg_fields() { JOIN_TAB *tab; JOIN_CACHE *cache; if (!is_key_access()) return; /* Save pointers to the cache fields in previous caches that are used to build keys for this key access. */ cache= this; uint ext_key_arg_cnt= external_key_arg_fields; CACHE_FIELD *copy; CACHE_FIELD **copy_ptr= blob_ptr; while (ext_key_arg_cnt) { cache= cache->prev_cache; for (tab= cache->start_tab; tab != cache->join_tab; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { CACHE_FIELD *copy_end; MY_BITMAP *key_read_set= &tab->table->tmp_set; /* key_read_set contains the bitmap of tab's fields referenced by ref */ if (bitmap_is_clear_all(key_read_set)) continue; copy_end= cache->field_descr+cache->fields; for (copy= cache->field_descr+cache->flag_fields; copy < copy_end; copy++) { /* (1) - when we store rowids for DuplicateWeedout, they have copy->field==NULL */ if (copy->field && // (1) copy->field->table == tab->table && bitmap_is_set(key_read_set, copy->field->field_index)) { *copy_ptr++= copy; ext_key_arg_cnt--; if (!copy->referenced_field_no) { /* Register the referenced field 'copy': - set the offset number in copy->referenced_field_no, - adjust the value of the flag 'with_length', - adjust the values of 'pack_length' and of 'pack_length_with_blob_ptrs'. */ copy->referenced_field_no= ++cache->referenced_fields; if (!cache->with_length) { cache->with_length= TRUE; uint sz= cache->get_size_of_rec_length(); cache->base_prefix_length+= sz; cache->pack_length+= sz; cache->pack_length_with_blob_ptrs+= sz; } cache->pack_length+= cache->get_size_of_fld_offset(); cache->pack_length_with_blob_ptrs+= cache->get_size_of_fld_offset(); } } } } } /* After this 'blob_ptr' shall not be be changed */ blob_ptr= copy_ptr; /* Now create local fields that are used to build ref for this key access */ copy= field_descr+flag_fields; for (tab= start_tab; tab != join_tab; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { length+= add_table_data_fields_to_join_cache(tab, &tab->table->tmp_set, &data_field_count, ©, &data_field_ptr_count, ©_ptr); } use_emb_key= check_emb_key_usage(); return; } /* Create descriptors of all remaining data fields stored in the join buffer SYNOPSIS create_remaining_fields() DESCRIPTION The function creates descriptors for all remaining data fields of a record from the join buffer. If the value returned by is_key_access() is false the function creates fields for all read record fields that comprise the partial join record joined with join_tab. Otherwise, for each table tab, the set of the read fields for which the descriptors have to be added is determined as the difference between all read fields and and those for which the descriptors have been already created. The latter are supposed to be marked in the bitmap tab->table->tmp_set. The function increases the value of 'length' to the the total length of the added fields. NOTES If is_key_access() returns true the function modifies the value of tab->table->tmp_set for a each table whose fields are stored in the cache. The function calls the method Field::fill_cache_field to figure out the type of the cache field and the maximal length of its representation in the join buffer. If this is a blob field then additionally a pointer to this field is added as an element of the array blob_ptr. For a blob field only the size of the length of the blob data is taken into account. It is assumed that 'data_field_count' contains the number of descriptors for data fields that have been already created and 'data_field_ptr_count' contains the number of the pointers to such descriptors having been stored up to the moment. RETURN VALUE none */ void JOIN_CACHE::create_remaining_fields() { JOIN_TAB *tab; bool all_read_fields= !is_key_access(); CACHE_FIELD *copy= field_descr+flag_fields+data_field_count; CACHE_FIELD **copy_ptr= blob_ptr+data_field_ptr_count; for (tab= start_tab; tab != join_tab; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { MY_BITMAP *rem_field_set; TABLE *table= tab->table; if (all_read_fields) rem_field_set= table->read_set; else { bitmap_invert(&table->tmp_set); bitmap_intersect(&table->tmp_set, table->read_set); rem_field_set= &table->tmp_set; } length+= add_table_data_fields_to_join_cache(tab, rem_field_set, &data_field_count, ©, &data_field_ptr_count, ©_ptr); /* SemiJoinDuplicateElimination: allocate space for rowid if needed */ if (tab->keep_current_rowid) { copy->str= table->file->ref; if (copy->str) copy->length= table->file->ref_length; else { /* This may happen only for materialized derived tables and views */ copy->length= 0; copy->str= (uchar *) table; } copy->type= CACHE_ROWID; copy->field= 0; copy->referenced_field_no= 0; /* Note: this may seem odd, but at this point we have table->file->ref==NULL while table->file->ref_length is already set to correct value. */ length += table->file->ref_length; data_field_count++; copy++; } } } /* Calculate and set all cache constants SYNOPSIS set_constants() DESCRIPTION The function calculates and set all precomputed constants that are used when writing records into the join buffer and reading them from it. It calculates the size of offsets of a record within the join buffer and of a field within a record. It also calculates the number of bytes used to store record lengths. The function also calculates the maximal length of the representation of record in the cache excluding blob_data. This value is used when making a dicision whether more records should be added into the join buffer or not. RETURN VALUE none */ void JOIN_CACHE::set_constants() { /* Any record from a BKA cache is prepended with the record length. We use the record length when reading the buffer and building key values for each record. The length allows us not to read the fields that are not needed for keys. If a record has match flag it also may be skipped when the match flag is on. It happens if the cache is used for a semi-join operation or for outer join when the 'not exist' optimization can be applied. If some of the fields are referenced from other caches then the record length allows us to easily reach the saved offsets for these fields since the offsets are stored at the very end of the record. However at this moment we don't know whether we have referenced fields for the cache or not. Later when a referenced field is registered for the cache we adjust the value of the flag 'with_length'. */ with_length= is_key_access() || join_tab->is_inner_table_of_semi_join_with_first_match() || join_tab->is_inner_table_of_outer_join(); /* At this moment we don't know yet the value of 'referenced_fields', but in any case it can't be greater than the value of 'fields'. */ uint len= length + fields*sizeof(uint)+blobs*sizeof(uchar *) + (prev_cache ? prev_cache->get_size_of_rec_offset() : 0) + sizeof(ulong); /* The values of size_of_rec_ofs, size_of_rec_len, size_of_fld_ofs, base_prefix_length, pack_length, pack_length_with_blob_ptrs will be recalculated later in this function when we get the estimate for the actual value of the join buffer size. */ size_of_rec_ofs= size_of_rec_len= size_of_fld_ofs= 4; base_prefix_length= (with_length ? size_of_rec_len : 0) + (prev_cache ? prev_cache->get_size_of_rec_offset() : 0); pack_length= (with_length ? size_of_rec_len : 0) + (prev_cache ? prev_cache->get_size_of_rec_offset() : 0) + length + fields*sizeof(uint); pack_length_with_blob_ptrs= pack_length + blobs*sizeof(uchar *); min_buff_size= 0; min_records= 1; buff_size= max(join->thd->variables.join_buff_size, get_min_join_buffer_size()); size_of_rec_ofs= offset_size(buff_size); size_of_rec_len= blobs ? size_of_rec_ofs : offset_size(len); size_of_fld_ofs= size_of_rec_len; base_prefix_length= (with_length ? size_of_rec_len : 0) + (prev_cache ? prev_cache->get_size_of_rec_offset() : 0); /* The size of the offsets for referenced fields will be added later. The values of 'pack_length' and 'pack_length_with_blob_ptrs' are adjusted every time when the first reference to the referenced field is registered. */ pack_length= (with_length ? size_of_rec_len : 0) + (prev_cache ? prev_cache->get_size_of_rec_offset() : 0) + length; pack_length_with_blob_ptrs= pack_length + blobs*sizeof(uchar *); } /* Get maximum total length of all affixes of a record in the join cache buffer SYNOPSIS get_record_max_affix_length() DESCRIPTION The function calculates the maximum possible total length of all affixes of a record in the join cache buffer, that is made of: - the length of all prefixes used in this cache, - the length of the match flag if it's needed - the total length of the maximum possible offsets to the fields of a record in the buffer. RETURN VALUE The maximum total length of all affixes of a record in the join buffer */ uint JOIN_CACHE::get_record_max_affix_length() { uint len= get_prefix_length() + test(with_match_flag) + size_of_fld_ofs * data_field_count; return len; } /* Get the minimum possible size of the cache join buffer SYNOPSIS get_min_join_buffer_size() DESCRIPTION At the first its invocation for the cache the function calculates the minimum possible size of the join buffer of the cache. This value depends on the minimal number of records 'min_records' to be stored in the join buffer. The number is supposed to be determined by the procedure that chooses the best access path to the joined table join_tab in the execution plan. After the calculation of the interesting size the function saves it in the field 'min_buff_size' in order to use it directly at the next invocations of the function. NOTES Currently the number of minimal records is just set to 1. RETURN VALUE The minimal possible size of the join buffer of this cache */ ulong JOIN_CACHE::get_min_join_buffer_size() { if (!min_buff_size) { size_t len= 0; size_t len_last= 0; for (JOIN_TAB *tab= start_tab; tab != join_tab; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { len+= tab->get_max_used_fieldlength(); len_last+= tab->get_used_fieldlength(); } size_t len_addon= get_record_max_affix_length() + get_max_key_addon_space_per_record(); len+= len_addon; len_last+= len_addon; size_t min_sz= len*(min_records-1) + len_last; min_sz+= pack_length_with_blob_ptrs; size_t add_sz= 0; for (uint i=0; i < min_records; i++) add_sz+= join_tab_scan->aux_buffer_incr(i+1); avg_aux_buffer_incr= add_sz/min_records; min_sz+= add_sz; set_if_bigger(min_sz, 1); min_buff_size= min_sz; } return min_buff_size; } /* Get the maximum possible size of the cache join buffer SYNOPSIS get_max_join_buffer_size() optimize_buff_size FALSE <-> do not take more memory than needed for the estimated number of records in the partial join DESCRIPTION At the first its invocation for the cache the function calculates the maximum possible size of join buffer for the cache. If the parameter optimize_buff_size true then this value does not exceed the size of the space needed for the estimated number of records 'max_records' in the partial join that joins tables from the first one through join_tab. This value is also capped off by the value of join_tab->join_buffer_size_limit, if it has been set a to non-zero value, and by the value of the system parameter join_buffer_size - otherwise. After the calculation of the interesting size the function saves the value in the field 'max_buff_size' in order to use it directly at the next invocations of the function. NOTES Currently the value of join_tab->join_buffer_size_limit is initialized to 0 and is never reset. RETURN VALUE The maximum possible size of the join buffer of this cache */ ulong JOIN_CACHE::get_max_join_buffer_size(bool optimize_buff_size) { if (!max_buff_size) { size_t max_sz; size_t min_sz= get_min_join_buffer_size(); size_t len= 0; for (JOIN_TAB *tab= start_tab; tab != join_tab; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { len+= tab->get_used_fieldlength(); } len+= get_record_max_affix_length(); avg_record_length= len; len+= get_max_key_addon_space_per_record() + avg_aux_buffer_incr; space_per_record= len; size_t limit_sz= join->thd->variables.join_buff_size; if (join_tab->join_buffer_size_limit) set_if_smaller(limit_sz, join_tab->join_buffer_size_limit); if (!optimize_buff_size) max_sz= limit_sz; else { if (limit_sz / max_records > space_per_record) max_sz= space_per_record * max_records; else max_sz= limit_sz; max_sz+= pack_length_with_blob_ptrs; set_if_smaller(max_sz, limit_sz); } set_if_bigger(max_sz, min_sz); max_buff_size= max_sz; } return max_buff_size; } /* Allocate memory for a join buffer SYNOPSIS alloc_buffer() DESCRIPTION The function allocates a lump of memory for the cache join buffer. Initially the function sets the size of the buffer buff_size equal to the value returned by get_max_join_buffer_size(). If the total size of the space intended to be used for the join buffers employed by the tables from the first one through join_tab exceeds the value of the system parameter join_buff_space_limit, then the function first tries to shrink the used buffers to make the occupied space fit the maximum memory allowed to be used for all join buffers in total. After this the function tries to allocate a join buffer for join_tab. If it fails to do so, it decrements the requested size of the join buffer, shrinks proportionally the join buffers used for the previous tables and tries to allocate a buffer for join_tab. In the case of a failure the function repeats its attempts with smaller and smaller requested sizes of the buffer, but not more than 4 times. RETURN VALUE 0 if the memory has been successfully allocated 1 otherwise */ int JOIN_CACHE::alloc_buffer() { JOIN_TAB *tab; JOIN_CACHE *cache; ulonglong curr_buff_space_sz= 0; ulonglong curr_min_buff_space_sz= 0; ulonglong join_buff_space_limit= join->thd->variables.join_buff_space_limit; bool optimize_buff_size= optimizer_flag(join->thd, OPTIMIZER_SWITCH_OPTIMIZE_JOIN_BUFFER_SIZE); double partial_join_cardinality= (join_tab-1)->get_partial_join_cardinality(); buff= NULL; min_buff_size= 0; max_buff_size= 0; min_records= 1; max_records= (size_t) (partial_join_cardinality <= join_buff_space_limit ? (ulonglong) partial_join_cardinality : join_buff_space_limit); set_if_bigger(max_records, 10); min_buff_size= get_min_join_buffer_size(); buff_size= get_max_join_buffer_size(optimize_buff_size); for (tab= start_tab; tab!= join_tab; tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS)) { cache= tab->cache; if (cache) { curr_min_buff_space_sz+= cache->get_min_join_buffer_size(); curr_buff_space_sz+= cache->get_join_buffer_size(); } } curr_min_buff_space_sz+= min_buff_size; curr_buff_space_sz+= buff_size; if (curr_min_buff_space_sz > join_buff_space_limit || (curr_buff_space_sz > join_buff_space_limit && (!optimize_buff_size || join->shrink_join_buffers(join_tab, curr_buff_space_sz, join_buff_space_limit)))) goto fail; for (ulong buff_size_decr= (buff_size-min_buff_size)/4 + 1; ; ) { ulong next_buff_size; if ((buff= (uchar*) my_malloc(buff_size, MYF(MY_THREAD_SPECIFIC)))) break; next_buff_size= buff_size > buff_size_decr ? buff_size-buff_size_decr : 0; if (next_buff_size < min_buff_size || join->shrink_join_buffers(join_tab, curr_buff_space_sz, curr_buff_space_sz-buff_size_decr)) goto fail; buff_size= next_buff_size; curr_buff_space_sz= 0; for (tab= join->join_tab+join->const_tables; tab <= join_tab; tab++) { cache= tab->cache; if (cache) curr_buff_space_sz+= cache->get_join_buffer_size(); } } return 0; fail: buff_size= 0; return 1; } /* Shrink the size if the cache join buffer in a given ratio SYNOPSIS shrink_join_buffer_in_ratio() n nominator of the ratio to shrink the buffer in d denominator if the ratio DESCRIPTION The function first deallocates the join buffer of the cache. Then it allocates a buffer that is (n/d) times smaller. RETURN VALUE FALSE on success with allocation of the smaller join buffer TRUE otherwise */ bool JOIN_CACHE::shrink_join_buffer_in_ratio(ulonglong n, ulonglong d) { size_t next_buff_size; if (n < d) return FALSE; next_buff_size= (size_t) ((double) buff_size / n * d); set_if_bigger(next_buff_size, min_buff_size); buff_size= next_buff_size; return realloc_buffer(); } /* Reallocate the join buffer of a join cache SYNOPSIS realloc_buffer() DESCRITION The function reallocates the join buffer of the join cache. After this it resets the buffer for writing. NOTES The function assumes that buff_size contains the new value for the join buffer size. RETURN VALUE 0 if the buffer has been successfully reallocated 1 otherwise */ int JOIN_CACHE::realloc_buffer() { int rc; free(); rc= test(!(buff= (uchar*) my_malloc(buff_size, MYF(MY_THREAD_SPECIFIC)))); reset(TRUE); return rc; } /* Initialize a join cache SYNOPSIS init() DESCRIPTION The function initializes the join cache structure. It supposed to be called by init methods for classes derived from the JOIN_CACHE. The function allocates memory for the join buffer and for descriptors of the record fields stored in the buffer. NOTES The code of this function should have been included into the constructor code itself. However the new operator for the class JOIN_CACHE would never fail while memory allocation for the join buffer is not absolutely unlikely to fail. That's why this memory allocation has to be placed in a separate function that is called in a couple with a cache constructor. It is quite natural to put almost all other constructor actions into this function. RETURN VALUE 0 initialization with buffer allocations has been succeeded 1 otherwise */ int JOIN_CACHE::init() { DBUG_ENTER("JOIN_CACHE::init"); calc_record_fields(); collect_info_on_key_args(); if (alloc_fields()) DBUG_RETURN(1); create_flag_fields(); create_key_arg_fields(); create_remaining_fields(); set_constants(); if (alloc_buffer()) DBUG_RETURN(1); reset(TRUE); DBUG_RETURN(0); } /* Check the possibility to read the access keys directly from the join buffer SYNOPSIS check_emb_key_usage() DESCRIPTION The function checks some conditions at which the key values can be read directly from the join buffer. This is possible when the key values can be composed by concatenation of the record fields stored in the join buffer. Sometimes when the access key is multi-component the function has to re-order the fields written into the join buffer to make keys embedded. If key values for the key access are detected as embedded then 'use_emb_key' is set to TRUE. EXAMPLE Let table t2 has an index defined on the columns a,b . Let's assume also that the columns t2.a, t2.b as well as the columns t1.a, t1.b are all of the integer type. Then if the query SELECT COUNT(*) FROM t1, t2 WHERE t1.a=t2.a and t1.b=t2.b is executed with a join cache in such a way that t1 is the driving table then the key values to access table t2 can be read directly from the join buffer. NOTES In some cases key values could be read directly from the join buffer but we still do not consider them embedded. In the future we'll expand the the class of keys which we identify as embedded. NOTES The function returns FALSE if no key is used to join the records from join_tab. RETURN VALUE TRUE key values will be considered as embedded, FALSE otherwise. */ bool JOIN_CACHE::check_emb_key_usage() { if (!is_key_access()) return FALSE; uint i; Item *item; KEY_PART_INFO *key_part; CACHE_FIELD *copy; CACHE_FIELD *copy_end; uint len= 0; TABLE_REF *ref= &join_tab->ref; KEY *keyinfo= join_tab->get_keyinfo_by_key_no(ref->key); /* If some of the key arguments are not from the local cache the key is not considered as embedded. TODO: Expand it to the case when ref->key_parts=1 and local_key_arg_fields=0. */ if (external_key_arg_fields != 0) return FALSE; /* If the number of the local key arguments is not equal to the number of key parts the key value cannot be read directly from the join buffer. */ if (local_key_arg_fields != ref->key_parts) return FALSE; /* A key is not considered embedded if one of the following is true: - one of its key parts is not equal to a field - it is a partial key - definition of the argument field does not coincide with the definition of the corresponding key component - some of the key components are nullable */ for (i=0; i < ref->key_parts; i++) { item= ref->items[i]->real_item(); if (item->type() != Item::FIELD_ITEM) return FALSE; key_part= keyinfo->key_part+i; if (key_part->key_part_flag & HA_PART_KEY_SEG) return FALSE; if (!key_part->field->eq_def(((Item_field *) item)->field)) return FALSE; if (key_part->field->maybe_null()) return FALSE; } copy= field_descr+flag_fields; copy_end= copy+local_key_arg_fields; for ( ; copy < copy_end; copy++) { /* If some of the key arguments are of variable length the key is not considered as embedded. */ if (copy->type != 0) return FALSE; /* If some of the key arguments are bit fields whose bits are partially stored with null bits the key is not considered as embedded. */ if (copy->field->type() == MYSQL_TYPE_BIT && ((Field_bit*) (copy->field))->bit_len) return FALSE; len+= copy->length; } emb_key_length= len; /* Make sure that key fields follow the order of the corresponding key components these fields are equal to. For this the descriptors of the fields that comprise the key might be re-ordered. */ for (i= 0; i < ref->key_parts; i++) { uint j; Item *item= ref->items[i]->real_item(); Field *fld= ((Item_field *) item)->field; CACHE_FIELD *init_copy= field_descr+flag_fields+i; for (j= i, copy= init_copy; i < local_key_arg_fields; i++, copy++) { if (fld->eq(copy->field)) { if (j != i) { CACHE_FIELD key_part_copy= *copy; *copy= *init_copy; *init_copy= key_part_copy; } break; } } } return TRUE; } /* Write record fields and their required offsets into the join cache buffer SYNOPSIS write_record_data() link a reference to the associated info in the previous cache is_full OUT true if it has been decided that no more records will be added to the join buffer DESCRIPTION This function put into the cache buffer the following info that it reads from the join record buffers or computes somehow: (1) the length of all fields written for the record (optional) (2) an offset to the associated info in the previous cache (if there is any) determined by the link parameter (3) all flag fields of the tables whose data field are put into the cache: - match flag (optional), - null bitmaps for all tables, - null row flags for all tables (4) values of all data fields including - full images of those fixed legth data fields that cannot have trailing spaces - significant part of fixed length fields that can have trailing spaces with the prepanded length - data of non-blob variable length fields with the prepanded data length - blob data from blob fields with the prepanded data length (5) record offset values for the data fields that are referred to from other caches The record is written at the current position stored in the field 'pos'. At the end of the function 'pos' points at the position right after the written record data. The function increments the number of records in the cache that is stored in the 'records' field by 1. The function also modifies the values of 'curr_rec_pos' and 'last_rec_pos' to point to the written record. The 'end_pos' cursor is modified accordingly. The 'last_rec_blob_data_is_in_rec_buff' is set on if the blob data remains in the record buffers and not copied to the join buffer. It may happen only to the blob data from the last record added into the cache. If on_precond is attached to join_tab and it is not evaluated to TRUE then MATCH_IMPOSSIBLE is placed in the match flag field of the record written into the join buffer. RETURN VALUE length of the written record data */ uint JOIN_CACHE::write_record_data(uchar * link, bool *is_full) { uint len; bool last_record; CACHE_FIELD *copy; CACHE_FIELD *copy_end; uchar *flags_pos; uchar *cp= pos; uchar *init_pos= cp; uchar *rec_len_ptr= 0; uint key_extra= extra_key_length(); records++; /* Increment the counter of records in the cache */ len= pack_length + key_extra; /* Make an adjustment for the size of the auxiliary buffer if there is any */ uint incr= aux_buffer_incr(records); size_t rem= rem_space(); aux_buff_size+= len+incr < rem ? incr : rem; /* For each blob to be put into cache save its length and a pointer to the value in the corresponding element of the blob_ptr array. Blobs with null values are skipped. Increment 'len' by the total length of all these blobs. */ if (blobs) { CACHE_FIELD **copy_ptr= blob_ptr; CACHE_FIELD **copy_ptr_end= copy_ptr+blobs; for ( ; copy_ptr < copy_ptr_end; copy_ptr++) { Field_blob *blob_field= (Field_blob *) (*copy_ptr)->field; if (!blob_field->is_null()) { uint blob_len= blob_field->get_length(); (*copy_ptr)->blob_length= blob_len; len+= blob_len; blob_field->get_ptr(&(*copy_ptr)->str); } } } /* Check whether we won't be able to add any new record into the cache after this one because the cache will be full. Set last_record to TRUE if it's so. The assume that the cache will be full after the record has been written into it if either the remaining space of the cache is not big enough for the record's blob values or if there is a chance that not all non-blob fields of the next record can be placed there. This function is called only in the case when there is enough space left in the cache to store at least non-blob parts of the current record. */ last_record= (len+pack_length_with_blob_ptrs+key_extra) > rem_space(); /* Save the position for the length of the record in the cache if it's needed. The length of the record will be inserted here when all fields of the record are put into the cache. */ if (with_length) { rec_len_ptr= cp; DBUG_ASSERT(cp + size_of_rec_len <= buff + buff_size); cp+= size_of_rec_len; } /* Put a reference to the fields of the record that are stored in the previous cache if there is any. This reference is passed by the 'link' parameter. */ if (prev_cache) { DBUG_ASSERT(cp + prev_cache->get_size_of_rec_offset() <= buff + buff_size); cp+= prev_cache->get_size_of_rec_offset(); prev_cache->store_rec_ref(cp, link); } curr_rec_pos= cp; /* If the there is a match flag set its value to 0 */ copy= field_descr; if (with_match_flag) *copy[0].str= 0; /* First put into the cache the values of all flag fields */ copy_end= field_descr+flag_fields; flags_pos= cp; for ( ; copy < copy_end; copy++) { DBUG_ASSERT(cp + copy->length <= buff + buff_size); memcpy(cp, copy->str, copy->length); cp+= copy->length; } /* Now put the values of the remaining fields as soon as they are not nulls */ copy_end= field_descr+fields; for ( ; copy < copy_end; copy++) { Field *field= copy->field; if (field && field->maybe_null() && field->is_null()) { if (copy->referenced_field_no) copy->offset= 0; continue; } /* Save the offset of the field to put it later at the end of the record */ if (copy->referenced_field_no) copy->offset= cp-curr_rec_pos; if (copy->type == CACHE_BLOB) { Field_blob *blob_field= (Field_blob *) copy->field; if (last_record) { last_rec_blob_data_is_in_rec_buff= 1; /* Put down the length of the blob and the pointer to the data */ DBUG_ASSERT(cp + copy->length + sizeof(char*) <= buff + buff_size); blob_field->get_image(cp, copy->length+sizeof(char*), blob_field->charset()); cp+= copy->length+sizeof(char*); } else { /* First put down the length of the blob and then copy the data */ blob_field->get_image(cp, copy->length, blob_field->charset()); DBUG_ASSERT(cp + copy->length + copy->blob_length <= buff + buff_size); memcpy(cp+copy->length, copy->str, copy->blob_length); cp+= copy->length+copy->blob_length; } } else { switch (copy->type) { case CACHE_VARSTR1: /* Copy the significant part of the short varstring field */ len= (uint) copy->str[0] + 1; DBUG_ASSERT(cp + len <= buff + buff_size); memcpy(cp, copy->str, len); cp+= len; break; case CACHE_VARSTR2: /* Copy the significant part of the long varstring field */ len= uint2korr(copy->str) + 2; DBUG_ASSERT(cp + len <= buff + buff_size); memcpy(cp, copy->str, len); cp+= len; break; case CACHE_STRIPPED: { /* Put down the field value stripping all trailing spaces off. After this insert the length of the written sequence of bytes. */ uchar *str, *end; for (str= copy->str, end= str+copy->length; end > str && end[-1] == ' '; end--) ; len=(uint) (end-str); DBUG_ASSERT(cp + len + 2 <= buff + buff_size); int2store(cp, len); memcpy(cp+2, str, len); cp+= len+2; break; } case CACHE_ROWID: if (!copy->length) { /* This may happen only for ROWID fields of materialized derived tables and views. */ TABLE *table= (TABLE *) copy->str; copy->str= table->file->ref; copy->length= table->file->ref_length; if (!copy->str) { /* If table is an empty inner table of an outer join and it is a materialized derived table then table->file->ref == NULL. */ cp+= copy->length; break; } } /* fall through */ default: /* Copy the entire image of the field from the record buffer */ DBUG_ASSERT(cp + copy->length <= buff + buff_size); if (copy->str) memcpy(cp, copy->str, copy->length); cp+= copy->length; } } } /* Add the offsets of the fields that are referenced from other caches */ if (referenced_fields) { uint cnt= 0; for (copy= field_descr+flag_fields; copy < copy_end ; copy++) { if (copy->referenced_field_no) { store_fld_offset(cp+size_of_fld_ofs*(copy->referenced_field_no-1), copy->offset); cnt++; } } DBUG_ASSERT(cp + size_of_fld_ofs*cnt <= buff + buff_size); cp+= size_of_fld_ofs*cnt; } if (rec_len_ptr) store_rec_length(rec_len_ptr, (ulong) (cp-rec_len_ptr-size_of_rec_len)); last_rec_pos= curr_rec_pos; end_pos= pos= cp; *is_full= last_record; last_written_is_null_compl= 0; if (!join_tab->first_unmatched && join_tab->on_precond) { join_tab->found= 0; join_tab->not_null_compl= 1; if (!join_tab->on_precond->val_int()) { flags_pos[0]= MATCH_IMPOSSIBLE; last_written_is_null_compl= 1; } } return (uint) (cp-init_pos); } /* Reset the join buffer for reading/writing: default implementation SYNOPSIS reset() for_writing if it's TRUE the function reset the buffer for writing DESCRIPTION This default implementation of the virtual function reset() resets the join buffer for reading or writing. If the buffer is reset for reading only the 'pos' value is reset to point to the very beginning of the join buffer. If the buffer is reset for writing additionally: - the counter of the records in the buffer is set to 0, - the the value of 'last_rec_pos' gets pointing at the position just before the buffer, - 'end_pos' is set to point to the beginning of the join buffer, - the size of the auxiliary buffer is reset to 0, - the flag 'last_rec_blob_data_is_in_rec_buff' is set to 0. RETURN VALUE none */ void JOIN_CACHE::reset(bool for_writing) { pos= buff; curr_rec_link= 0; if (for_writing) { records= 0; last_rec_pos= buff; aux_buff_size= 0; end_pos= pos; last_rec_blob_data_is_in_rec_buff= 0; } } /* Add a record into the join buffer: the default implementation SYNOPSIS put_record() DESCRIPTION This default implementation of the virtual function put_record writes the next matching record into the join buffer. It also links the record having been written into the join buffer with the matched record in the previous cache if there is any. The implementation assumes that the function get_curr_link() will return exactly the pointer to this matched record. RETURN VALUE TRUE if it has been decided that it should be the last record in the join buffer, FALSE otherwise */ bool JOIN_CACHE::put_record() { bool is_full; uchar *link= 0; if (prev_cache) link= prev_cache->get_curr_rec_link(); write_record_data(link, &is_full); return is_full; } /* Read the next record from the join buffer: the default implementation SYNOPSIS get_record() DESCRIPTION This default implementation of the virtual function get_record reads fields of the next record from the join buffer of this cache. The function also reads all other fields associated with this record from the the join buffers of the previous caches. The fields are read into the corresponding record buffers. It is supposed that 'pos' points to the position in the buffer right after the previous record when the function is called. When the function returns the 'pos' values is updated to point to the position after the read record. The value of 'curr_rec_pos' is also updated by the function to point to the beginning of the first field of the record in the join buffer. RETURN VALUE TRUE there are no more records to read from the join buffer FALSE otherwise */ bool JOIN_CACHE::get_record() { bool res; uchar *prev_rec_ptr= 0; if (with_length) pos+= size_of_rec_len; if (prev_cache) { pos+= prev_cache->get_size_of_rec_offset(); prev_rec_ptr= prev_cache->get_rec_ref(pos); } curr_rec_pos= pos; if (!(res= read_all_record_fields() == NO_MORE_RECORDS_IN_BUFFER)) { pos+= referenced_fields*size_of_fld_ofs; if (prev_cache) prev_cache->get_record_by_pos(prev_rec_ptr); } return res; } /* Read a positioned record from the join buffer: the default implementation SYNOPSIS get_record_by_pos() rec_ptr position of the first field of the record in the join buffer DESCRIPTION This default implementation of the virtual function get_record_pos reads the fields of the record positioned at 'rec_ptr' from the join buffer. The function also reads all other fields associated with this record from the the join buffers of the previous caches. The fields are read into the corresponding record buffers. RETURN VALUE none */ void JOIN_CACHE::get_record_by_pos(uchar *rec_ptr) { uchar *save_pos= pos; pos= rec_ptr; read_all_record_fields(); pos= save_pos; if (prev_cache) { uchar *prev_rec_ptr= prev_cache->get_rec_ref(rec_ptr); prev_cache->get_record_by_pos(prev_rec_ptr); } } /* Get the match flag from the referenced record: the default implementation SYNOPSIS get_match_flag_by_pos() rec_ptr position of the first field of the record in the join buffer DESCRIPTION This default implementation of the virtual function get_match_flag_by_pos get the match flag for the record pointed by the reference at the position rec_ptr. If the match flag is placed in one of the previous buffers the function first reaches the linked record fields in this buffer. RETURN VALUE match flag for the record at the position rec_ptr */ enum JOIN_CACHE::Match_flag JOIN_CACHE::get_match_flag_by_pos(uchar *rec_ptr) { Match_flag match_fl= MATCH_NOT_FOUND; if (with_match_flag) { match_fl= (enum Match_flag) rec_ptr[0]; return match_fl; } if (prev_cache) { uchar *prev_rec_ptr= prev_cache->get_rec_ref(rec_ptr); return prev_cache->get_match_flag_by_pos(prev_rec_ptr); } DBUG_ASSERT(0); return match_fl; } /* Calculate the increment of the auxiliary buffer for a record write SYNOPSIS aux_buffer_incr() recno the number of the record the increment to be calculated for DESCRIPTION This function calls the aux_buffer_incr the method of the companion member join_tab_scan to calculate the growth of the auxiliary buffer when the recno-th record is added to the join_buffer of this cache. RETURN VALUE the number of bytes in the increment */ uint JOIN_CACHE::aux_buffer_incr(ulong recno) { return join_tab_scan->aux_buffer_incr(recno); } /* Read all flag and data fields of a record from the join buffer SYNOPSIS read_all_record_fields() DESCRIPTION The function reads all flag and data fields of a record from the join buffer into the corresponding record buffers. The fields are read starting from the position 'pos' which is supposed to point to the beginning og the first record field. The function increments the value of 'pos' by the length of the read data. RETURN VALUE (-1) if there is no more records in the join buffer length of the data read from the join buffer - otherwise */ uint JOIN_CACHE::read_all_record_fields() { uchar *init_pos= pos; if (pos > last_rec_pos || !records) return NO_MORE_RECORDS_IN_BUFFER; /* First match flag, read null bitmaps and null_row flag for each table */ read_flag_fields(); /* Now read the remaining table fields if needed */ CACHE_FIELD *copy= field_descr+flag_fields; CACHE_FIELD *copy_end= field_descr+fields; bool blob_in_rec_buff= blob_data_is_in_rec_buff(init_pos); for ( ; copy < copy_end; copy++) read_record_field(copy, blob_in_rec_buff); return (uint) (pos-init_pos); } /* Read all flag fields of a record from the join buffer SYNOPSIS read_flag_fields() DESCRIPTION The function reads all flag fields of a record from the join buffer into the corresponding record buffers. The fields are read starting from the position 'pos'. The function increments the value of 'pos' by the length of the read data. RETURN VALUE length of the data read from the join buffer */ uint JOIN_CACHE::read_flag_fields() { uchar *init_pos= pos; CACHE_FIELD *copy= field_descr; CACHE_FIELD *copy_end= copy+flag_fields; if (with_match_flag) { copy->str[0]= test((Match_flag) pos[0] == MATCH_FOUND); pos+= copy->length; copy++; } for ( ; copy < copy_end; copy++) { memcpy(copy->str, pos, copy->length); pos+= copy->length; } return (pos-init_pos); } /* Read a data record field from the join buffer SYNOPSIS read_record_field() copy the descriptor of the data field to be read blob_in_rec_buff indicates whether this is the field from the record whose blob data are in record buffers DESCRIPTION The function reads the data field specified by the parameter copy from the join buffer into the corresponding record buffer. The field is read starting from the position 'pos'. The data of blob values is not copied from the join buffer. The function increments the value of 'pos' by the length of the read data. RETURN VALUE length of the data read from the join buffer */ uint JOIN_CACHE::read_record_field(CACHE_FIELD *copy, bool blob_in_rec_buff) { uint len; /* Do not copy the field if its value is null */ if (copy->field && copy->field->maybe_null() && copy->field->is_null()) return 0; if (copy->type == CACHE_BLOB) { Field_blob *blob_field= (Field_blob *) copy->field; /* Copy the length and the pointer to data but not the blob data itself to the record buffer */ if (blob_in_rec_buff) { blob_field->set_image(pos, copy->length+sizeof(char*), blob_field->charset()); len= copy->length+sizeof(char*); } else { blob_field->set_ptr(pos, pos+copy->length); len= copy->length+blob_field->get_length(); } } else { switch (copy->type) { case CACHE_VARSTR1: /* Copy the significant part of the short varstring field */ len= (uint) pos[0] + 1; memcpy(copy->str, pos, len); break; case CACHE_VARSTR2: /* Copy the significant part of the long varstring field */ len= uint2korr(pos) + 2; memcpy(copy->str, pos, len); break; case CACHE_STRIPPED: /* Pad the value by spaces that has been stripped off */ len= uint2korr(pos); memcpy(copy->str, pos+2, len); memset(copy->str+len, ' ', copy->length-len); len+= 2; break; case CACHE_ROWID: if (!copy->str) { len= copy->length; break; } /* fall through */ default: /* Copy the entire image of the field from the record buffer */ len= copy->length; memcpy(copy->str, pos, len); } } pos+= len; return len; } /* Read a referenced field from the join buffer SYNOPSIS read_referenced_field() copy pointer to the descriptor of the referenced field rec_ptr pointer to the record that may contain this field len IN/OUT total length of the record fields DESCRIPTION The function checks whether copy points to a data field descriptor for this cache object. If it does not then the function returns FALSE. Otherwise the function reads the field of the record in the join buffer pointed by 'rec_ptr' into the corresponding record buffer and returns TRUE. If the value of *len is 0 then the function sets it to the total length of the record fields including possible trailing offset values. Otherwise *len is supposed to provide this value that has been obtained earlier. NOTE If the value of the referenced field is null then the offset for the value is set to 0. If the value of a field can be null then the value of flag_fields is always positive. So the offset for any non-null value cannot be 0 in this case. RETURN VALUE TRUE 'copy' points to a data descriptor of this join cache FALSE otherwise */ bool JOIN_CACHE::read_referenced_field(CACHE_FIELD *copy, uchar *rec_ptr, uint *len) { uchar *ptr; uint offset; if (copy < field_descr || copy >= field_descr+fields) return FALSE; if (!*len) { /* Get the total length of the record fields */ uchar *len_ptr= rec_ptr; if (prev_cache) len_ptr-= prev_cache->get_size_of_rec_offset(); *len= get_rec_length(len_ptr-size_of_rec_len); } ptr= rec_ptr-(prev_cache ? prev_cache->get_size_of_rec_offset() : 0); offset= get_fld_offset(ptr+ *len - size_of_fld_ofs* (referenced_fields+1-copy->referenced_field_no)); bool is_null= FALSE; Field *field= copy->field; if (offset == 0 && flag_fields) is_null= TRUE; if (is_null) { field->set_null(); if (!field->real_maybe_null()) field->table->null_row= 1; } else { uchar *save_pos= pos; field->set_notnull(); if (!field->real_maybe_null()) field->table->null_row= 0; pos= rec_ptr+offset; read_record_field(copy, blob_data_is_in_rec_buff(rec_ptr)); pos= save_pos; } return TRUE; } /* Skip record from join buffer if's already matched: default implementation SYNOPSIS skip_if_matched() DESCRIPTION This default implementation of the virtual function skip_if_matched skips the next record from the join buffer if its match flag is set to MATCH_FOUND. If the record is skipped the value of 'pos' is set to point to the position right after the record. RETURN VALUE TRUE the match flag is set to MATCH_FOUND and the record has been skipped FALSE otherwise */ bool JOIN_CACHE::skip_if_matched() { DBUG_ASSERT(with_length); uint offset= size_of_rec_len; if (prev_cache) offset+= prev_cache->get_size_of_rec_offset(); /* Check whether the match flag is MATCH_FOUND */ if (get_match_flag_by_pos(pos+offset) == MATCH_FOUND) { pos+= size_of_rec_len + get_rec_length(pos); return TRUE; } return FALSE; } /* Skip record from join buffer if the match isn't needed: default implementation SYNOPSIS skip_if_not_needed_match() DESCRIPTION This default implementation of the virtual function skip_if_not_needed_match skips the next record from the join buffer if its match flag is not MATCH_NOT_FOUND, and, either its value is MATCH_FOUND and join_tab is the first inner table of an inner join, or, its value is MATCH_IMPOSSIBLE and join_tab is the first inner table of an outer join. If the record is skipped the value of 'pos' is set to point to the position right after the record. RETURN VALUE TRUE the record has to be skipped FALSE otherwise */ bool JOIN_CACHE::skip_if_not_needed_match() { DBUG_ASSERT(with_length); enum Match_flag match_fl; uint offset= size_of_rec_len; if (prev_cache) offset+= prev_cache->get_size_of_rec_offset(); if ((match_fl= get_match_flag_by_pos(pos+offset)) != MATCH_NOT_FOUND && (join_tab->check_only_first_match() == (match_fl == MATCH_FOUND)) ) { pos+= size_of_rec_len + get_rec_length(pos); return TRUE; } return FALSE; } /* Restore the fields of the last record from the join buffer SYNOPSIS restore_last_record() DESCRIPTION This function restore the values of the fields of the last record put into join buffer in record buffers. The values most probably have been overwritten by the field values from other records when they were read from the join buffer into the record buffer in order to check pushdown predicates. RETURN none */ void JOIN_CACHE::restore_last_record() { if (records) get_record_by_pos(last_rec_pos); } /* Join records from the join buffer with records from the next join table SYNOPSIS join_records() skip_last do not find matches for the last record from the buffer DESCRIPTION The functions extends all records from the join buffer by the matched records from join_tab. In the case of outer join operation it also adds null complementing extensions for the records from the join buffer that have no match. No extensions are generated for the last record from the buffer if skip_last is true. NOTES The function must make sure that if linked join buffers are used then a join buffer cannot be refilled again until all extensions in the buffers chained to this one are generated. Currently an outer join operation with several inner tables always uses at least two linked buffers with the match join flags placed in the first buffer. Any record composed of rows of the inner tables that matches a record in this buffer must refer to the position of the corresponding match flag. IMPLEMENTATION When generating extensions for outer tables of an outer join operation first we generate all extensions for those records from the join buffer that have matches, after which null complementing extension for all unmatched records from the join buffer are generated. RETURN VALUE return one of enum_nested_loop_state, except NESTED_LOOP_NO_MORE_ROWS. */ enum_nested_loop_state JOIN_CACHE::join_records(bool skip_last) { JOIN_TAB *tab; enum_nested_loop_state rc= NESTED_LOOP_OK; bool outer_join_first_inner= join_tab->is_first_inner_for_outer_join(); DBUG_ENTER("JOIN_CACHE::join_records"); if (outer_join_first_inner && !join_tab->first_unmatched) join_tab->not_null_compl= TRUE; if (!join_tab->first_unmatched) { /* Find all records from join_tab that match records from join buffer */ rc= join_matching_records(skip_last); if (rc != NESTED_LOOP_OK && rc != NESTED_LOOP_NO_MORE_ROWS) goto finish; if (outer_join_first_inner) { if (next_cache) { /* Ensure that all matches for outer records from join buffer are to be found. Now we ensure that all full records are found for records from join buffer. Generally this is an overkill. TODO: Ensure that only matches of the inner table records have to be found for the records from join buffer. */ rc= next_cache->join_records(skip_last); if (rc != NESTED_LOOP_OK && rc != NESTED_LOOP_NO_MORE_ROWS) goto finish; } join_tab->not_null_compl= FALSE; /* Prepare for generation of null complementing extensions */ for (tab= join_tab->first_inner; tab <= join_tab->last_inner; tab++) tab->first_unmatched= join_tab->first_inner; } } if (join_tab->first_unmatched) { if (is_key_access()) restore_last_record(); /* Generate all null complementing extensions for the records from join buffer that don't have any matching rows from the inner tables. */ reset(FALSE); rc= join_null_complements(skip_last); if (rc != NESTED_LOOP_OK && rc != NESTED_LOOP_NO_MORE_ROWS) goto finish; } if(next_cache) { /* When using linked caches we must ensure the records in the next caches that refer to the records in the join buffer are fully extended. Otherwise we could have references to the records that have been already erased from the join buffer and replaced for new records. */ rc= next_cache->join_records(skip_last); if (rc != NESTED_LOOP_OK && rc != NESTED_LOOP_NO_MORE_ROWS) goto finish; } if (skip_last) { DBUG_ASSERT(!is_key_access()); /* Restore the last record from the join buffer to generate all extentions for it. */ get_record(); } finish: if (outer_join_first_inner) { /* All null complemented rows have been already generated for all outer records from join buffer. Restore the state of the first_unmatched values to 0 to avoid another null complementing. */ for (tab= join_tab->first_inner; tab <= join_tab->last_inner; tab++) tab->first_unmatched= 0; } restore_last_record(); reset(TRUE); DBUG_PRINT("exit", ("rc: %d", rc)); DBUG_RETURN(rc); } /* Find matches from the next table for records from the join buffer SYNOPSIS join_matching_records() skip_last do not look for matches for the last partial join record DESCRIPTION The function retrieves rows of the join_tab table and checks whether they match partial join records from the join buffer. If a match is found the function will call the sub_select function trying to look for matches for the remaining join operations. This function currently is called only from the function join_records. If the value of skip_last is true the function writes the partial join record from the record buffer into the join buffer to save its value for the future processing in the caller function. NOTES If employed by BNL or BNLH join algorithms the function performs a full scan of join_tab for each refill of the join buffer. If BKA or BKAH algorithms are used then the function iterates only over those records from join_tab that can be accessed by keys built over records in the join buffer. To apply a proper method of iteration the function just calls virtual iterator methods (open, next, close) of the member join_tab_scan. The member can be either of the JOIN_TAB_SCAN or JOIN_TAB_SCAN_MMR type. The class JOIN_TAB_SCAN provides the iterator methods for BNL/BNLH join algorithms. The class JOIN_TAB_SCAN_MRR provides the iterator methods for BKA/BKAH join algorithms. When the function looks for records from the join buffer that would match a record from join_tab it iterates either over all records in the buffer or only over selected records. If BNL join operation is performed all records are checked for the match. If BNLH or BKAH algorithm is employed to join join_tab then the function looks only through the records with the same join key as the record from join_tab. With the BKA join algorithm only one record from the join buffer is checked for a match for any record from join_tab. To iterate over the candidates for a match the virtual function get_next_candidate_for_match is used, while the virtual function prepare_look_for_matches is called to prepare for such iteration proccess. NOTES The function produces all matching extensions for the records in the join buffer following the path of the employed blocked algorithm. When an outer join operation is performed all unmatched records from the join buffer must be extended by null values. The function 'join_null_complements' serves this purpose. RETURN VALUE return one of enum_nested_loop_state */ enum_nested_loop_state JOIN_CACHE::join_matching_records(bool skip_last) { int error; enum_nested_loop_state rc= NESTED_LOOP_OK; join_tab->table->null_row= 0; bool check_only_first_match= join_tab->check_only_first_match(); bool outer_join_first_inner= join_tab->is_first_inner_for_outer_join(); DBUG_ENTER("JOIN_CACHE::join_matching_records"); /* Return at once if there are no records in the join buffer */ if (!records) DBUG_RETURN(NESTED_LOOP_OK); /* When joining we read records from the join buffer back into record buffers. If matches for the last partial join record are found through a call to the sub_select function then this partial join record must be saved in the join buffer in order to be restored just before the sub_select call. */ if (skip_last) put_record(); if (join_tab->use_quick == 2 && join_tab->select->quick) { /* A dynamic range access was used last. Clean up after it */ delete join_tab->select->quick; join_tab->select->quick= 0; } if ((rc= join_tab_execution_startup(join_tab)) < 0) goto finish2; /* Prepare to retrieve all records of the joined table */ if ((error= join_tab_scan->open())) { /* TODO: if we get here, we will assert in net_send_statement(). Add test coverage and fix. */ goto finish; } while (!(error= join_tab_scan->next())) { if (join->thd->check_killed()) { /* The user has aborted the execution of the query */ join->thd->send_kill_message(); rc= NESTED_LOOP_KILLED; goto finish; } if (join_tab->keep_current_rowid) join_tab->table->file->position(join_tab->table->record[0]); /* Prepare to read matching candidates from the join buffer */ if (prepare_look_for_matches(skip_last)) continue; uchar *rec_ptr; /* Read each possible candidate from the buffer and look for matches */ while ((rec_ptr= get_next_candidate_for_match())) { /* If only the first match is needed, and, it has been already found for the next record read from the join buffer, then the record is skipped. Also those records that must be null complemented are not considered as candidates for matches. */ if ((!check_only_first_match && !outer_join_first_inner) || !skip_next_candidate_for_match(rec_ptr)) { read_next_candidate_for_match(rec_ptr); rc= generate_full_extensions(rec_ptr); if (rc != NESTED_LOOP_OK && rc != NESTED_LOOP_NO_MORE_ROWS) goto finish; } } } finish: if (error) rc= error < 0 ? NESTED_LOOP_NO_MORE_ROWS: NESTED_LOOP_ERROR; finish2: join_tab_scan->close(); DBUG_RETURN(rc); } /* Set match flag for a record in join buffer if it has not been set yet SYNOPSIS set_match_flag_if_none() first_inner the join table to which this flag is attached to rec_ptr pointer to the record in the join buffer DESCRIPTION If the records of the table are accumulated in a join buffer the function sets the match flag for the record in the buffer that is referred to by the record from this cache positioned at 'rec_ptr'. The function also sets the match flag 'found' of the table first inner if it has not been set before. NOTES The function assumes that the match flag for any record in any cache is placed in the first byte occupied by the record fields. RETURN VALUE TRUE the match flag is set by this call for the first time FALSE the match flag has been set before this call */ bool JOIN_CACHE::set_match_flag_if_none(JOIN_TAB *first_inner, uchar *rec_ptr) { if (!first_inner->cache) { /* Records of the first inner table to which the flag is attached to are not accumulated in a join buffer. */ if (first_inner->found) return FALSE; else { first_inner->found= 1; return TRUE; } } JOIN_CACHE *cache= this; while (cache->join_tab != first_inner) { cache= cache->prev_cache; DBUG_ASSERT(cache); rec_ptr= cache->get_rec_ref(rec_ptr); } if ((Match_flag) rec_ptr[0] != MATCH_FOUND) { rec_ptr[0]= MATCH_FOUND; first_inner->found= 1; return TRUE; } return FALSE; } /* Generate all full extensions for a partial join record in the buffer SYNOPSIS generate_full_extensions() rec_ptr pointer to the record from join buffer to generate extensions DESCRIPTION The function first checks whether the current record of 'join_tab' matches the partial join record from join buffer located at 'rec_ptr'. If it is the case the function calls the join_tab->next_select method to generate all full extension for this partial join match. RETURN VALUE return one of enum_nested_loop_state. */ enum_nested_loop_state JOIN_CACHE::generate_full_extensions(uchar *rec_ptr) { enum_nested_loop_state rc= NESTED_LOOP_OK; DBUG_ENTER("JOIN_CACHE::generate_full_extensions"); /* Check whether the extended partial join record meets the pushdown conditions. */ if (check_match(rec_ptr)) { int res= 0; if (!join_tab->check_weed_out_table || !(res= join_tab->check_weed_out_table->sj_weedout_check_row(join->thd))) { set_curr_rec_link(rec_ptr); rc= (join_tab->next_select)(join, join_tab+1, 0); if (rc != NESTED_LOOP_OK && rc != NESTED_LOOP_NO_MORE_ROWS) { reset(TRUE); DBUG_RETURN(rc); } } if (res == -1) { rc= NESTED_LOOP_ERROR; DBUG_RETURN(rc); } } else if (join->thd->is_error()) rc= NESTED_LOOP_ERROR; DBUG_RETURN(rc); } /* Check matching to a partial join record from the join buffer SYNOPSIS check_match() rec_ptr pointer to the record from join buffer to check matching to DESCRIPTION The function checks whether the current record of 'join_tab' matches the partial join record from join buffer located at 'rec_ptr'. If this is the case and 'join_tab' is the last inner table of a semi-join or an outer join the function turns on the match flag for the 'rec_ptr' record unless it has been already set. NOTES Setting the match flag on can trigger re-evaluation of pushdown conditions for the record when join_tab is the last inner table of an outer join. RETURN VALUE TRUE there is a match FALSE there is no match In this case the caller must also check thd->is_error() to see if there was a fatal error for the query. */ inline bool JOIN_CACHE::check_match(uchar *rec_ptr) { /* Check whether pushdown conditions are satisfied */ DBUG_ENTER("JOIN_CACHE:check_match"); if (join_tab->select && join_tab->select->skip_record(join->thd) <= 0) DBUG_RETURN(FALSE); if (!join_tab->is_last_inner_table()) DBUG_RETURN(TRUE); /* This is the last inner table of an outer join, and maybe of other embedding outer joins, or this is the last inner table of a semi-join. */ JOIN_TAB *first_inner= join_tab->get_first_inner_table(); do { set_match_flag_if_none(first_inner, rec_ptr); if (first_inner->check_only_first_match() && !join_tab->first_inner) DBUG_RETURN(TRUE); /* This is the first match for the outer table row. The function set_match_flag_if_none has turned the flag first_inner->found on. The pushdown predicates for inner tables must be re-evaluated with this flag on. Note that, if first_inner is the first inner table of a semi-join, but is not an inner table of an outer join such that 'not exists' optimization can be applied to it, the re-evaluation of the pushdown predicates is not needed. */ for (JOIN_TAB *tab= first_inner; tab <= join_tab; tab++) { if (tab->select && tab->select->skip_record(join->thd) <= 0) DBUG_RETURN(FALSE); } } while ((first_inner= first_inner->first_upper) && first_inner->last_inner == join_tab); DBUG_RETURN(TRUE); } /* Add null complements for unmatched outer records from join buffer SYNOPSIS join_null_complements() skip_last do not add null complements for the last record DESCRIPTION This function is called only for inner tables of outer joins. The function retrieves all rows from the join buffer and adds null complements for those of them that do not have matches for outer table records. If the 'join_tab' is the last inner table of the embedding outer join and the null complemented record satisfies the outer join condition then the the corresponding match flag is turned on unless it has been set earlier. This setting may trigger re-evaluation of pushdown conditions for the record. NOTES The same implementation of the virtual method join_null_complements is used for BNL/BNLH/BKA/BKA join algorthm. RETURN VALUE return one of enum_nested_loop_state. */ enum_nested_loop_state JOIN_CACHE::join_null_complements(bool skip_last) { ulonglong cnt; enum_nested_loop_state rc= NESTED_LOOP_OK; bool is_first_inner= join_tab == join_tab->first_unmatched; DBUG_ENTER("JOIN_CACHE::join_null_complements"); /* Return at once if there are no records in the join buffer */ if (!records) DBUG_RETURN(NESTED_LOOP_OK); cnt= records - (is_key_access() ? 0 : test(skip_last)); /* This function may be called only for inner tables of outer joins */ DBUG_ASSERT(join_tab->first_inner); for ( ; cnt; cnt--) { if (join->thd->check_killed()) { /* The user has aborted the execution of the query */ join->thd->send_kill_message(); rc= NESTED_LOOP_KILLED; goto finish; } /* Just skip the whole record if a match for it has been already found */ if (!is_first_inner || !skip_if_matched()) { get_record(); /* The outer row is complemented by nulls for each inner table */ restore_record(join_tab->table, s->default_values); mark_as_null_row(join_tab->table); rc= generate_full_extensions(get_curr_rec()); if (rc != NESTED_LOOP_OK && rc != NESTED_LOOP_NO_MORE_ROWS) goto finish; } } finish: DBUG_RETURN(rc); } /* Add a comment on the join algorithm employed by the join cache SYNOPSIS print_explain_comment() str string to add the comment on the employed join algorithm to DESCRIPTION This function adds info on the type of the used join buffer (flat or incremental) and on the type of the the employed join algorithm (BNL, BNLH, BKA or BKAH) to the the end of the sring str. RETURN VALUE none */ void JOIN_CACHE::print_explain_comment(String *str) { str->append(STRING_WITH_LEN(" (")); const char *buffer_type= prev_cache ? "incremental" : "flat"; str->append(buffer_type); str->append(STRING_WITH_LEN(", ")); const char *join_alg=""; switch (get_join_alg()) { case BNL_JOIN_ALG: join_alg= "BNL"; break; case BNLH_JOIN_ALG: join_alg= "BNLH"; break; case BKA_JOIN_ALG: join_alg= "BKA"; break; case BKAH_JOIN_ALG: join_alg= "BKAH"; break; default: DBUG_ASSERT(0); } str->append(join_alg); str->append(STRING_WITH_LEN(" join")); str->append(STRING_WITH_LEN(")")); } /** get thread handle. */ THD *JOIN_CACHE::thd() { return join->thd; } static void add_mrr_explain_info(String *str, uint mrr_mode, handler *file) { char mrr_str_buf[128]={0}; int len; len= file->multi_range_read_explain_info(mrr_mode, mrr_str_buf, sizeof(mrr_str_buf)); if (len > 0) { str->append(STRING_WITH_LEN("; ")); str->append(mrr_str_buf, len); } } void JOIN_CACHE_BKA::print_explain_comment(String *str) { JOIN_CACHE::print_explain_comment(str); add_mrr_explain_info(str, mrr_mode, join_tab->table->file); } void JOIN_CACHE_BKAH::print_explain_comment(String *str) { JOIN_CACHE::print_explain_comment(str); add_mrr_explain_info(str, mrr_mode, join_tab->table->file); } /* Initialize a hashed join cache SYNOPSIS init() DESCRIPTION The function initializes the cache structure with a hash table in it. The hash table will be used to store key values for the records from the join buffer. The function allocates memory for the join buffer and for descriptors of the record fields stored in the buffer. The function also initializes a hash table for record keys within the join buffer space. NOTES VALUE The function is supposed to be called by the init methods of the classes derived from JOIN_CACHE_HASHED. RETURN VALUE 0 initialization with buffer allocations has been succeeded 1 otherwise */ int JOIN_CACHE_HASHED::init() { int rc= 0; TABLE_REF *ref= &join_tab->ref; DBUG_ENTER("JOIN_CACHE_HASHED::init"); hash_table= 0; key_entries= 0; key_length= ref->key_length; if ((rc= JOIN_CACHE::init())) DBUG_RETURN (rc); if (!(key_buff= (uchar*) sql_alloc(key_length))) DBUG_RETURN(1); /* Take into account a reference to the next record in the key chain */ pack_length+= get_size_of_rec_offset(); pack_length_with_blob_ptrs+= get_size_of_rec_offset(); ref_key_info= join_tab->get_keyinfo_by_key_no(join_tab->ref.key); ref_used_key_parts= join_tab->ref.key_parts; hash_func= &JOIN_CACHE_HASHED::get_hash_idx_simple; hash_cmp_func= &JOIN_CACHE_HASHED::equal_keys_simple; KEY_PART_INFO *key_part= ref_key_info->key_part; KEY_PART_INFO *key_part_end= key_part+ref_used_key_parts; for ( ; key_part < key_part_end; key_part++) { if (!key_part->field->eq_cmp_as_binary()) { hash_func= &JOIN_CACHE_HASHED::get_hash_idx_complex; hash_cmp_func= &JOIN_CACHE_HASHED::equal_keys_complex; break; } } init_hash_table(); rec_fields_offset= get_size_of_rec_offset()+get_size_of_rec_length()+ (prev_cache ? prev_cache->get_size_of_rec_offset() : 0); data_fields_offset= 0; if (use_emb_key) { CACHE_FIELD *copy= field_descr; CACHE_FIELD *copy_end= copy+flag_fields; for ( ; copy < copy_end; copy++) data_fields_offset+= copy->length; } DBUG_RETURN(rc); } /* Initialize the hash table of a hashed join cache SYNOPSIS init_hash_table() DESCRIPTION The function estimates the number of hash table entries in the hash table to be used and initializes this hash table within the join buffer space. RETURN VALUE Currently the function always returns 0; */ int JOIN_CACHE_HASHED::init_hash_table() { hash_table= 0; key_entries= 0; /* Calculate the minimal possible value of size_of_key_ofs greater than 1 */ uint max_size_of_key_ofs= max(2, get_size_of_rec_offset()); for (size_of_key_ofs= 2; size_of_key_ofs <= max_size_of_key_ofs; size_of_key_ofs+= 2) { key_entry_length= get_size_of_rec_offset() + // key chain header size_of_key_ofs + // reference to the next key (use_emb_key ? get_size_of_rec_offset() : key_length); ulong space_per_rec= avg_record_length + avg_aux_buffer_incr + key_entry_length+size_of_key_ofs; uint n= buff_size / space_per_rec; /* TODO: Make a better estimate for this upper bound of the number of records in in the join buffer. */ uint max_n= buff_size / (pack_length-length+ key_entry_length+size_of_key_ofs); hash_entries= (uint) (n / 0.7); set_if_bigger(hash_entries, 1); if (offset_size(max_n*key_entry_length) <= size_of_key_ofs) break; } /* Initialize the hash table */ hash_table= buff + (buff_size-hash_entries*size_of_key_ofs); cleanup_hash_table(); curr_key_entry= hash_table; return 0; } /* Reallocate the join buffer of a hashed join cache SYNOPSIS realloc_buffer() DESCRITION The function reallocates the join buffer of the hashed join cache. After this it initializes a hash table within the buffer space and resets the join cache for writing. NOTES The function assumes that buff_size contains the new value for the join buffer size. RETURN VALUE 0 if the buffer has been successfully reallocated 1 otherwise */ int JOIN_CACHE_HASHED::realloc_buffer() { int rc; free(); rc= test(!(buff= (uchar*) my_malloc(buff_size, MYF(MY_THREAD_SPECIFIC)))); init_hash_table(); reset(TRUE); return rc; } /* Get maximum size of the additional space per record used for record keys SYNOPSYS get_max_key_addon_space_per_record() DESCRIPTION The function returns the size of the space occupied by one key entry and one hash table entry. RETURN VALUE maximum size of the additional space per record that is used to store record keys in the hash table */ uint JOIN_CACHE_HASHED::get_max_key_addon_space_per_record() { ulong len; TABLE_REF *ref= &join_tab->ref; /* The total number of hash entries in the hash tables is bounded by ceiling(N/0.7) where N is the maximum number of records in the buffer. That's why the multiplier 2 is used in the formula below. */ len= (use_emb_key ? get_size_of_rec_offset() : ref->key_length) + size_of_rec_ofs + // size of the key chain header size_of_rec_ofs + // >= size of the reference to the next key 2*size_of_rec_ofs; // >= 2*( size of hash table entry) return len; } /* Reset the buffer of a hashed join cache for reading/writing SYNOPSIS reset() for_writing if it's TRUE the function reset the buffer for writing DESCRIPTION This implementation of the virtual function reset() resets the join buffer of the JOIN_CACHE_HASHED class for reading or writing. Additionally to what the default implementation does this function cleans up the hash table allocated within the buffer. RETURN VALUE none */ void JOIN_CACHE_HASHED::reset(bool for_writing) { this->JOIN_CACHE::reset(for_writing); if (for_writing && hash_table) cleanup_hash_table(); curr_key_entry= hash_table; } /* Add a record into the buffer of a hashed join cache SYNOPSIS put_record() DESCRIPTION This implementation of the virtual function put_record writes the next matching record into the join buffer of the JOIN_CACHE_HASHED class. Additionally to what the default implementation does this function performs the following. It extracts from the record the key value used in lookups for matching records and searches for this key in the hash tables from the join cache. If it finds the key in the hash table it joins the record to the chain of records with this key. If the key is not found in the hash table the key is placed into it and a chain containing only the newly added record is attached to the key entry. The key value is either placed in the hash element added for the key or, if the use_emb_key flag is set, remains in the record from the partial join. If the match flag field of a record contains MATCH_IMPOSSIBLE the key is not created for this record. RETURN VALUE TRUE if it has been decided that it should be the last record in the join buffer, FALSE otherwise */ bool JOIN_CACHE_HASHED::put_record() { bool is_full; uchar *key; uint key_len= key_length; uchar *key_ref_ptr; uchar *link= 0; TABLE_REF *ref= &join_tab->ref; uchar *next_ref_ptr= pos; pos+= get_size_of_rec_offset(); /* Write the record into the join buffer */ if (prev_cache) link= prev_cache->get_curr_rec_link(); write_record_data(link, &is_full); if (last_written_is_null_compl) return is_full; if (use_emb_key) key= get_curr_emb_key(); else { /* Build the key over the fields read into the record buffers */ cp_buffer_from_ref(join->thd, join_tab->table, ref); key= ref->key_buff; } /* Look for the key in the hash table */ if (key_search(key, key_len, &key_ref_ptr)) { uchar *last_next_ref_ptr; /* The key is found in the hash table. Add the record to the circular list of the records attached to this key. Below 'rec' is the record to be added into the record chain for the found key, 'key_ref' points to a flatten representation of the st_key_entry structure that contains the key and the head of the record chain. */ last_next_ref_ptr= get_next_rec_ref(key_ref_ptr+get_size_of_key_offset()); /* rec->next_rec= key_entry->last_rec->next_rec */ memcpy(next_ref_ptr, last_next_ref_ptr, get_size_of_rec_offset()); /* key_entry->last_rec->next_rec= rec */ store_next_rec_ref(last_next_ref_ptr, next_ref_ptr); /* key_entry->last_rec= rec */ store_next_rec_ref(key_ref_ptr+get_size_of_key_offset(), next_ref_ptr); } else { /* The key is not found in the hash table. Put the key into the join buffer linking it with the keys for the corresponding hash entry. Create a circular list with one element referencing the record and attach the list to the key in the buffer. */ uchar *cp= last_key_entry; cp-= get_size_of_rec_offset()+get_size_of_key_offset(); store_next_key_ref(key_ref_ptr, cp); store_null_key_ref(cp); store_next_rec_ref(next_ref_ptr, next_ref_ptr); store_next_rec_ref(cp+get_size_of_key_offset(), next_ref_ptr); if (use_emb_key) { cp-= get_size_of_rec_offset(); store_emb_key_ref(cp, key); } else { cp-= key_len; memcpy(cp, key, key_len); } last_key_entry= cp; DBUG_ASSERT(last_key_entry >= end_pos); /* Increment the counter of key_entries in the hash table */ key_entries++; } return is_full; } /* Read the next record from the buffer of a hashed join cache SYNOPSIS get_record() DESCRIPTION Additionally to what the default implementation of the virtual function get_record does this implementation skips the link element used to connect the records with the same key into a chain. RETURN VALUE TRUE there are no more records to read from the join buffer FALSE otherwise */ bool JOIN_CACHE_HASHED::get_record() { pos+= get_size_of_rec_offset(); return this->JOIN_CACHE::get_record(); } /* Skip record from a hashed join buffer if its match flag is set to MATCH_FOUND SYNOPSIS skip_if_matched() DESCRIPTION This implementation of the virtual function skip_if_matched does the same as the default implementation does, but it takes into account the link element used to connect the records with the same key into a chain. RETURN VALUE TRUE the match flag is MATCH_FOUND and the record has been skipped FALSE otherwise */ bool JOIN_CACHE_HASHED::skip_if_matched() { uchar *save_pos= pos; pos+= get_size_of_rec_offset(); if (!this->JOIN_CACHE::skip_if_matched()) { pos= save_pos; return FALSE; } return TRUE; } /* Skip record from a hashed join buffer if its match flag dictates to do so SYNOPSIS skip_if_uneeded_match() DESCRIPTION This implementation of the virtual function skip_if_not_needed_match does the same as the default implementation does, but it takes into account the link element used to connect the records with the same key into a chain. RETURN VALUE TRUE the match flag dictates to skip the record FALSE the match flag is off */ bool JOIN_CACHE_HASHED::skip_if_not_needed_match() { uchar *save_pos= pos; pos+= get_size_of_rec_offset(); if (!this->JOIN_CACHE::skip_if_not_needed_match()) { pos= save_pos; return FALSE; } return TRUE; } /* Search for a key in the hash table of the join buffer SYNOPSIS key_search() key pointer to the key value key_len key value length key_ref_ptr OUT position of the reference to the next key from the hash element for the found key , or a position where the reference to the the hash element for the key is to be added in the case when the key has not been found DESCRIPTION The function looks for a key in the hash table of the join buffer. If the key is found the functionreturns the position of the reference to the next key from to the hash element for the given key. Otherwise the function returns the position where the reference to the newly created hash element for the given key is to be added. RETURN VALUE TRUE the key is found in the hash table FALSE otherwise */ bool JOIN_CACHE_HASHED::key_search(uchar *key, uint key_len, uchar **key_ref_ptr) { bool is_found= FALSE; uint idx= (this->*hash_func)(key, key_length); uchar *ref_ptr= hash_table+size_of_key_ofs*idx; while (!is_null_key_ref(ref_ptr)) { uchar *next_key; ref_ptr= get_next_key_ref(ref_ptr); next_key= use_emb_key ? get_emb_key(ref_ptr-get_size_of_rec_offset()) : ref_ptr-key_length; if ((this->*hash_cmp_func)(next_key, key, key_len)) { is_found= TRUE; break; } } *key_ref_ptr= ref_ptr; return is_found; } /* Hash function that considers a key in the hash table as byte array SYNOPSIS get_hash_idx_simple() key pointer to the key value key_len key value length DESCRIPTION The function calculates an index of the hash entry in the hash table of the join buffer for the given key. It considers the key just as a sequence of bytes of the length key_len. RETURN VALUE the calculated index of the hash entry for the given key */ inline uint JOIN_CACHE_HASHED::get_hash_idx_simple(uchar* key, uint key_len) { ulong nr= 1; ulong nr2= 4; uchar *pos= key; uchar *end= key+key_len; for (; pos < end ; pos++) { nr^= (ulong) ((((uint) nr & 63)+nr2)*((uint) *pos))+ (nr << 8); nr2+= 3; } return nr % hash_entries; } /* Hash function that takes into account collations of the components of the key SYNOPSIS get_hash_idx_complex() key pointer to the key value key_len key value length DESCRIPTION The function calculates an index of the hash entry in the hash table of the join buffer for the given key. It takes into account that the components of the key may be of a varchar type with different collations. The function guarantees that the same hash value for any two equal keys that may differ as byte sequences. The function takes the info about the components of the key, their types and used collations from the class member ref_key_info containing a pointer to the descriptor of the index that can be used for the join operation. RETURN VALUE the calculated index of the hash entry for the given key */ inline uint JOIN_CACHE_HASHED::get_hash_idx_complex(uchar *key, uint key_len) { return (uint) (key_hashnr(ref_key_info, ref_used_key_parts, key) % hash_entries); } /* Compare two key entries in the hash table as sequence of bytes SYNOPSIS equal_keys_simple() key1 pointer to the first key entry key2 pointer to the second key entry key_len the length of the key values DESCRIPTION The function compares two key entries in the hash table key1 and key2 as two sequences bytes of the length key_len RETURN VALUE TRUE key1 coincides with key2 FALSE otherwise */ inline bool JOIN_CACHE_HASHED::equal_keys_simple(uchar *key1, uchar *key2, uint key_len) { return memcmp(key1, key2, key_len) == 0; } /* Compare two key entries taking into account the used collation SYNOPSIS equal_keys_complex() key1 pointer to the first key entry key2 pointer to the second key entry key_len the length of the key values DESCRIPTION The function checks whether two key entries in the hash table key1 and key2 are equal as, possibly, compound keys of a certain structure whose components may be of a varchar type and may employ different collations. The descriptor of the key structure is taken from the class member ref_key_info. RETURN VALUE TRUE key1 is equal tokey2 FALSE otherwise */ inline bool JOIN_CACHE_HASHED::equal_keys_complex(uchar *key1, uchar *key2, uint key_len) { return key_buf_cmp(ref_key_info, ref_used_key_parts, key1, key2) == 0; } /* Clean up the hash table of the join buffer SYNOPSIS cleanup_hash_table() key pointer to the key value key_len key value length DESCRIPTION The function cleans up the hash table in the join buffer removing all hash elements from the table. RETURN VALUE none */ void JOIN_CACHE_HASHED:: cleanup_hash_table() { last_key_entry= hash_table; bzero(hash_table, (buff+buff_size)-hash_table); key_entries= 0; } /* Check whether all records in a key chain have their match flags set on SYNOPSIS check_all_match_flags_for_key() key_chain_ptr DESCRIPTION This function retrieves records in the given circular chain and checks whether their match flags are set on. The parameter key_chain_ptr shall point to the position in the join buffer storing the reference to the last element of this chain. RETURN VALUE TRUE if each retrieved record has its match flag set to MATCH_FOUND FALSE otherwise */ bool JOIN_CACHE_HASHED::check_all_match_flags_for_key(uchar *key_chain_ptr) { uchar *last_rec_ref_ptr= get_next_rec_ref(key_chain_ptr); uchar *next_rec_ref_ptr= last_rec_ref_ptr; do { next_rec_ref_ptr= get_next_rec_ref(next_rec_ref_ptr); uchar *rec_ptr= next_rec_ref_ptr+rec_fields_offset; if (get_match_flag_by_pos(rec_ptr) != MATCH_FOUND) return FALSE; } while (next_rec_ref_ptr != last_rec_ref_ptr); return TRUE; } /* Get the next key built for the records from the buffer of a hashed join cache SYNOPSIS get_next_key() key pointer to the buffer where the key value is to be placed DESCRIPTION The function reads the next key value stored in the hash table of the join buffer. Depending on the value of the use_emb_key flag of the join cache the value is read either from the table itself or from the record field where it occurs. RETURN VALUE length of the key value - if the starting value of 'cur_key_entry' refers to the position after that referred by the the value of 'last_key_entry', 0 - otherwise. */ uint JOIN_CACHE_HASHED::get_next_key(uchar ** key) { if (curr_key_entry == last_key_entry) return 0; curr_key_entry-= key_entry_length; *key = use_emb_key ? get_emb_key(curr_key_entry) : curr_key_entry; DBUG_ASSERT(*key >= buff && *key < hash_table); return key_length; } /* Initiate an iteration process over records in the joined table SYNOPSIS open() DESCRIPTION The function initiates the process of iteration over records from the joined table recurrently performed by the BNL/BKLH join algorithm. RETURN VALUE 0 the initiation is a success error code otherwise */ int JOIN_TAB_SCAN::open() { save_or_restore_used_tabs(join_tab, FALSE); is_first_record= TRUE; return join_init_read_record(join_tab); } /* Read the next record that can match while scanning the joined table SYNOPSIS next() DESCRIPTION The function reads the next record from the joined table that can match some records in the buffer of the join cache 'cache'. To do this the function calls the function that scans table records and looks for the next one that meets the condition pushed to the joined table join_tab. NOTES The function catches the signal that kills the query. RETURN VALUE 0 the next record exists and has been successfully read error code otherwise */ int JOIN_TAB_SCAN::next() { int err= 0; int skip_rc; READ_RECORD *info= &join_tab->read_record; SQL_SELECT *select= join_tab->cache_select; TABLE *table= join_tab->table; THD *thd= join->thd; if (is_first_record) is_first_record= FALSE; else err= info->read_record(info); if (!err && table->vfield) update_virtual_fields(thd, table); while (!err && select && (skip_rc= select->skip_record(thd)) <= 0) { if (thd->check_killed() || skip_rc < 0) return 1; /* Move to the next record if the last retrieved record does not meet the condition pushed to the table join_tab. */ err= info->read_record(info); if (!err && table->vfield) update_virtual_fields(thd, table); } return err; } /* Walk back in join order from join_tab until we encounter a join tab with tab->cache!=NULL, and save/restore tab->table->status along the way. @param save TRUE save FALSE restore */ static void save_or_restore_used_tabs(JOIN_TAB *join_tab, bool save) { JOIN_TAB *first= join_tab->bush_root_tab? join_tab->bush_root_tab->bush_children->start : join_tab->join->join_tab + join_tab->join->const_tables; for (JOIN_TAB *tab= join_tab-1; tab != first && !tab->cache; tab--) { if (tab->bush_children) { for (JOIN_TAB *child= tab->bush_children->start; child != tab->bush_children->end; child++) { if (save) child->table->status= child->status; else { tab->status= tab->table->status; tab->table->status= 0; } } } if (save) tab->table->status= tab->status; else { tab->status= tab->table->status; tab->table->status= 0; } } } /* Perform finalizing actions for a scan over the table records SYNOPSIS close() DESCRIPTION The function performs the necessary restoring actions after the table scan over the joined table has been finished. RETURN VALUE none */ void JOIN_TAB_SCAN::close() { save_or_restore_used_tabs(join_tab, TRUE); } /* Prepare to iterate over the BNL join cache buffer to look for matches SYNOPSIS prepare_look_for_matches() skip_last <-> ignore the last record in the buffer DESCRIPTION The function prepares the join cache for an iteration over the records in the join buffer. The iteration is performed when looking for matches for the record from the joined table join_tab that has been placed into the record buffer of the joined table. If the value of the parameter skip_last is TRUE then the last record from the join buffer is ignored. The function initializes the counter of the records that have been not iterated over yet. RETURN VALUE TRUE there are no records in the buffer to iterate over FALSE otherwise */ bool JOIN_CACHE_BNL::prepare_look_for_matches(bool skip_last) { if (!records) return TRUE; reset(FALSE); rem_records= records-test(skip_last); return rem_records == 0; } /* Get next record from the BNL join cache buffer when looking for matches SYNOPSIS get_next_candidate_for_match DESCRIPTION This method is used for iterations over the records from the join cache buffer when looking for matches for records from join_tab. The methods performs the necessary preparations to read the next record from the join buffer into the record buffer by the method read_next_candidate_for_match, or, to skip the next record from the join buffer by the method skip_recurrent_candidate_for_match. This implementation of the virtual method get_next_candidate_for_match just decrements the counter of the records that are to be iterated over and returns the current value of the cursor 'pos' as the position of the record to be processed. RETURN VALUE pointer to the position right after the prefix of the current record in the join buffer if the there is another record to iterate over, 0 - otherwise. */ uchar *JOIN_CACHE_BNL::get_next_candidate_for_match() { if (!rem_records) return 0; rem_records--; return pos+base_prefix_length; } /* Check whether the matching record from the BNL cache is to be skipped SYNOPSIS skip_next_candidate_for_match rec_ptr pointer to the position in the join buffer right after the prefix of the current record DESCRIPTION This implementation of the virtual function just calls the method skip_if_not_needed_match to check whether the record referenced by ref_ptr has its match flag set either to MATCH_FOUND and join_tab is the first inner table of a semi-join, or it's set to MATCH_IMPOSSIBLE and join_tab is the first inner table of an outer join. If so, the function just skips this record setting the value of the cursor 'pos' to the position right after it. RETURN VALUE TRUE the record referenced by rec_ptr has been skipped FALSE otherwise */ bool JOIN_CACHE_BNL::skip_next_candidate_for_match(uchar *rec_ptr) { pos= rec_ptr-base_prefix_length; return skip_if_not_needed_match(); } /* Read next record from the BNL join cache buffer when looking for matches SYNOPSIS read_next_candidate_for_match rec_ptr pointer to the position in the join buffer right after the prefix the current record. DESCRIPTION This implementation of the virtual method read_next_candidate_for_match calls the method get_record to read the record referenced by rec_ptr from the join buffer into the record buffer. If this record refers to the fields in the other join buffers the call of get_record ensures that these fields are read into the corresponding record buffers as well. This function is supposed to be called after a successful call of the method get_next_candidate_for_match. RETURN VALUE none */ void JOIN_CACHE_BNL::read_next_candidate_for_match(uchar *rec_ptr) { pos= rec_ptr-base_prefix_length; get_record(); } /* Initialize the BNL join cache SYNOPSIS init DESCRIPTION The function initializes the cache structure. It is supposed to be called right after a constructor for the JOIN_CACHE_BNL. NOTES The function first constructs a companion object of the type JOIN_TAB_SCAN, then it calls the init method of the parent class. RETURN VALUE 0 initialization with buffer allocations has been succeeded 1 otherwise */ int JOIN_CACHE_BNL::init() { DBUG_ENTER("JOIN_CACHE_BNL::init"); if (!(join_tab_scan= new JOIN_TAB_SCAN(join, join_tab))) DBUG_RETURN(1); DBUG_RETURN(JOIN_CACHE::init()); } /* Get the chain of records from buffer matching the current candidate for join SYNOPSIS get_matching_chain_by_join_key() DESCRIPTION This function first build a join key for the record of join_tab that currently is in the join buffer for this table. Then it looks for the key entry with this key in the hash table of the join cache. If such a key entry is found the function returns the pointer to the head of the chain of records in the join_buffer that match this key. RETURN VALUE The pointer to the corresponding circular list of records if the key entry with the join key is found, 0 - otherwise. */ uchar *JOIN_CACHE_BNLH::get_matching_chain_by_join_key() { uchar *key_ref_ptr; TABLE *table= join_tab->table; TABLE_REF *ref= &join_tab->ref; KEY *keyinfo= join_tab->get_keyinfo_by_key_no(ref->key); /* Build the join key value out of the record in the record buffer */ key_copy(key_buff, table->record[0], keyinfo, key_length, TRUE); /* Look for this key in the join buffer */ if (!key_search(key_buff, key_length, &key_ref_ptr)) return 0; return key_ref_ptr+get_size_of_key_offset(); } /* Prepare to iterate over the BNLH join cache buffer to look for matches SYNOPSIS prepare_look_for_matches() skip_last <-> ignore the last record in the buffer DESCRIPTION The function prepares the join cache for an iteration over the records in the join buffer. The iteration is performed when looking for matches for the record from the joined table join_tab that has been placed into the record buffer of the joined table. If the value of the parameter skip_last is TRUE then the last record from the join buffer is ignored. The function builds the hashed key from the join fields of join_tab and uses this key to look in the hash table of the join cache for the chain of matching records in in the join buffer. If it finds such a chain it sets the member last_rec_ref_ptr to point to the last link of the chain while setting the member next_rec_ref_po 0. RETURN VALUE TRUE there are no matching records in the buffer to iterate over FALSE otherwise */ bool JOIN_CACHE_BNLH::prepare_look_for_matches(bool skip_last) { uchar *curr_matching_chain; last_matching_rec_ref_ptr= next_matching_rec_ref_ptr= 0; if (!(curr_matching_chain= get_matching_chain_by_join_key())) return 1; last_matching_rec_ref_ptr= get_next_rec_ref(curr_matching_chain); return 0; } /* Get next record from the BNLH join cache buffer when looking for matches SYNOPSIS get_next_candidate_for_match DESCRIPTION This method is used for iterations over the records from the join cache buffer when looking for matches for records from join_tab. The methods performs the necessary preparations to read the next record from the join buffer into the record buffer by the method read_next_candidate_for_match, or, to skip the next record from the join buffer by the method skip_next_candidate_for_match. This implementation of the virtual method moves to the next record in the chain of all records from the join buffer that are to be equi-joined with the current record from join_tab. RETURN VALUE pointer to the beginning of the record fields in the join buffer if the there is another record to iterate over, 0 - otherwise. */ uchar *JOIN_CACHE_BNLH::get_next_candidate_for_match() { if (next_matching_rec_ref_ptr == last_matching_rec_ref_ptr) return 0; next_matching_rec_ref_ptr= get_next_rec_ref(next_matching_rec_ref_ptr ? next_matching_rec_ref_ptr : last_matching_rec_ref_ptr); return next_matching_rec_ref_ptr+rec_fields_offset; } /* Check whether the matching record from the BNLH cache is to be skipped SYNOPSIS skip_next_candidate_for_match rec_ptr pointer to the position in the join buffer right after the previous record DESCRIPTION This implementation of the virtual function just calls the method get_match_flag_by_pos to check whether the record referenced by ref_ptr has its match flag set to MATCH_FOUND. RETURN VALUE TRUE the record referenced by rec_ptr has its match flag set to MATCH_FOUND FALSE otherwise */ bool JOIN_CACHE_BNLH::skip_next_candidate_for_match(uchar *rec_ptr) { return join_tab->check_only_first_match() && (get_match_flag_by_pos(rec_ptr) == MATCH_FOUND); } /* Read next record from the BNLH join cache buffer when looking for matches SYNOPSIS read_next_candidate_for_match rec_ptr pointer to the position in the join buffer right after the previous record DESCRIPTION This implementation of the virtual method read_next_candidate_for_match calls the method get_record_by_pos to read the record referenced by rec_ptr from the join buffer into the record buffer. If this record refers to fields in the other join buffers the call of get_record_by_po ensures that these fields are read into the corresponding record buffers as well. This function is supposed to be called after a successful call of the method get_next_candidate_for_match. RETURN VALUE none */ void JOIN_CACHE_BNLH::read_next_candidate_for_match(uchar *rec_ptr) { get_record_by_pos(rec_ptr); } /* Initialize the BNLH join cache SYNOPSIS init DESCRIPTION The function initializes the cache structure. It is supposed to be called right after a constructor for the JOIN_CACHE_BNLH. NOTES The function first constructs a companion object of the type JOIN_TAB_SCAN, then it calls the init method of the parent class. RETURN VALUE 0 initialization with buffer allocations has been succeeded 1 otherwise */ int JOIN_CACHE_BNLH::init() { DBUG_ENTER("JOIN_CACHE_BNLH::init"); if (!(join_tab_scan= new JOIN_TAB_SCAN(join, join_tab))) DBUG_RETURN(1); DBUG_RETURN(JOIN_CACHE_HASHED::init()); } /* Calculate the increment of the MRR buffer for a record write SYNOPSIS aux_buffer_incr() DESCRIPTION This implementation of the virtual function aux_buffer_incr determines for how much the size of the MRR buffer should be increased when another record is added to the cache. RETURN VALUE the increment of the size of the MRR buffer for the next record */ uint JOIN_TAB_SCAN_MRR::aux_buffer_incr(ulong recno) { uint incr= 0; TABLE_REF *ref= &join_tab->ref; TABLE *tab= join_tab->table; ha_rows rec_per_key= (ha_rows) tab->key_info[ref->key].actual_rec_per_key(ref->key_parts-1); set_if_bigger(rec_per_key, 1); if (recno == 1) incr= ref->key_length + tab->file->ref_length; incr+= tab->file->stats.mrr_length_per_rec * rec_per_key; return incr; } /* Initiate iteration over records returned by MRR for the current join buffer SYNOPSIS open() DESCRIPTION The function initiates the process of iteration over the records from join_tab returned by the MRR interface functions for records from the join buffer. Such an iteration is performed by the BKA/BKAH join algorithm for each new refill of the join buffer. The function calls the MRR handler function multi_range_read_init to initiate this process. RETURN VALUE 0 the initiation is a success error code otherwise */ int JOIN_TAB_SCAN_MRR::open() { handler *file= join_tab->table->file; join_tab->table->null_row= 0; /* Dynamic range access is never used with BKA */ DBUG_ASSERT(join_tab->use_quick != 2); save_or_restore_used_tabs(join_tab, FALSE); init_mrr_buff(); /* Prepare to iterate over keys from the join buffer and to get matching candidates obtained with MMR handler functions. */ if (!file->inited) file->ha_index_init(join_tab->ref.key, 1); ranges= cache->get_number_of_ranges_for_mrr(); if (!join_tab->cache_idx_cond) range_seq_funcs.skip_index_tuple= 0; return file->multi_range_read_init(&range_seq_funcs, (void*) cache, ranges, mrr_mode, &mrr_buff); } /* Read the next record returned by MRR for the current join buffer SYNOPSIS next() DESCRIPTION The function reads the next record from the joined table join_tab returned by the MRR handler function multi_range_read_next for the current refill of the join buffer. The record is read into the record buffer used for join_tab records in join operations. RETURN VALUE 0 the next record exists and has been successfully read error code otherwise */ int JOIN_TAB_SCAN_MRR::next() { char **ptr= (char **) cache->get_curr_association_ptr(); DBUG_ASSERT(sizeof(range_id_t) == sizeof(*ptr)); int rc= join_tab->table->file->multi_range_read_next((range_id_t*)ptr) ? -1 : 0; if (!rc) { /* If a record in in an incremental cache contains no fields then the association for the last record in cache will be equal to cache->end_pos */ /* psergey: this makes no sense where HA_MRR_NO_ASSOC is used. DBUG_ASSERT(cache->buff <= (uchar *) (*ptr) && (uchar *) (*ptr) <= cache->end_pos); */ if (join_tab->table->vfield) update_virtual_fields(join->thd, join_tab->table); } return rc; } static void bka_range_seq_key_info(void *init_params, uint *length, key_part_map *map) { TABLE_REF *ref= &(((JOIN_CACHE*)init_params)->join_tab->ref); *length= ref->key_length; *map= (key_part_map(1) << ref->key_parts) - 1; } /* Initialize retrieval of range sequence for BKA join algorithm SYNOPSIS bka_range_seq_init() init_params pointer to the BKA join cache object n_ranges the number of ranges obtained flags combination of MRR flags DESCRIPTION The function interprets init_param as a pointer to a JOIN_CACHE_BKA object. The function prepares for an iteration over the join keys built for all records from the cache join buffer. NOTE This function are used only as a callback function. RETURN VALUE init_param value that is to be used as a parameter of bka_range_seq_next() */ static range_seq_t bka_range_seq_init(void *init_param, uint n_ranges, uint flags) { DBUG_ENTER("bka_range_seq_init"); JOIN_CACHE_BKA *cache= (JOIN_CACHE_BKA *) init_param; cache->reset(0); DBUG_RETURN((range_seq_t) init_param); } /* Get the next range/key over records from the join buffer used by a BKA cache SYNOPSIS bka_range_seq_next() seq the value returned by bka_range_seq_init range OUT reference to the next range DESCRIPTION The function interprets seq as a pointer to a JOIN_CACHE_BKA object. The function returns a pointer to the range descriptor for the key built over the next record from the join buffer. NOTE This function are used only as a callback function. RETURN VALUE FALSE ok, the range structure filled with info about the next range/key TRUE no more ranges */ static bool bka_range_seq_next(range_seq_t rseq, KEY_MULTI_RANGE *range) { DBUG_ENTER("bka_range_seq_next"); JOIN_CACHE_BKA *cache= (JOIN_CACHE_BKA *) rseq; TABLE_REF *ref= &cache->join_tab->ref; key_range *start_key= &range->start_key; if ((start_key->length= cache->get_next_key((uchar **) &start_key->key))) { start_key->keypart_map= (1 << ref->key_parts) - 1; start_key->flag= HA_READ_KEY_EXACT; range->end_key= *start_key; range->end_key.flag= HA_READ_AFTER_KEY; range->ptr= (char *) cache->get_curr_rec(); range->range_flag= EQ_RANGE; DBUG_RETURN(0); } DBUG_RETURN(1); } /* Check whether range_info orders to skip the next record from BKA buffer SYNOPSIS bka_range_seq_skip_record() seq value returned by bka_range_seq_init() range_info information about the next range rowid [NOT USED] rowid of the record to be checked DESCRIPTION The function interprets seq as a pointer to a JOIN_CACHE_BKA object. The function returns TRUE if the record with this range_info is to be filtered out from the stream of records returned by multi_range_read_next(). NOTE This function are used only as a callback function. RETURN VALUE 1 record with this range_info is to be filtered out from the stream of records returned by multi_range_read_next() 0 the record is to be left in the stream */ static bool bka_range_seq_skip_record(range_seq_t rseq, range_id_t range_info, uchar *rowid) { DBUG_ENTER("bka_range_seq_skip_record"); JOIN_CACHE_BKA *cache= (JOIN_CACHE_BKA *) rseq; bool res= cache->get_match_flag_by_pos((uchar *) range_info) == JOIN_CACHE::MATCH_FOUND; DBUG_RETURN(res); } /* Check if the record combination from BKA cache matches the index condition SYNOPSIS bka_skip_index_tuple() rseq value returned by bka_range_seq_init() range_info record chain for the next range/key returned by MRR DESCRIPTION This is wrapper for JOIN_CACHE_BKA::skip_index_tuple method, see comments there. NOTE This function is used as a RANGE_SEQ_IF::skip_index_tuple callback. RETURN VALUE 0 The record combination satisfies the index condition 1 Otherwise */ static bool bka_skip_index_tuple(range_seq_t rseq, range_id_t range_info) { DBUG_ENTER("bka_skip_index_tuple"); JOIN_CACHE_BKA *cache= (JOIN_CACHE_BKA *) rseq; THD *thd= cache->thd(); bool res; status_var_increment(thd->status_var.ha_icp_attempts); if (!(res= cache->skip_index_tuple(range_info))) status_var_increment(thd->status_var.ha_icp_match); DBUG_RETURN(res); } /* Prepare to read the record from BKA cache matching the current joined record SYNOPSIS prepare_look_for_matches() skip_last <-> ignore the last record in the buffer (always unused here) DESCRIPTION The function prepares to iterate over records in the join cache buffer matching the record loaded into the record buffer for join_tab when performing join operation by BKA join algorithm. With BKA algorithms the record loaded into the record buffer for join_tab always has a direct reference to the matching records from the join buffer. When the regular BKA join algorithm is employed the record from join_tab can refer to only one such record. The function sets the counter of the remaining records from the cache buffer that would match the current join_tab record to 1. RETURN VALUE TRUE there are no records in the buffer to iterate over FALSE otherwise */ bool JOIN_CACHE_BKA::prepare_look_for_matches(bool skip_last) { if (!records) return TRUE; rem_records= 1; return FALSE; } /* Get the record from the BKA cache matching the current joined record SYNOPSIS get_next_candidate_for_match DESCRIPTION This method is used for iterations over the records from the join cache buffer when looking for matches for records from join_tab. The method performs the necessary preparations to read the next record from the join buffer into the record buffer by the method read_next_candidate_for_match, or, to skip the next record from the join buffer by the method skip_if_not_needed_match. This implementation of the virtual method get_next_candidate_for_match just decrements the counter of the records that are to be iterated over and returns the value of curr_association as a reference to the position of the beginning of the record fields in the buffer. RETURN VALUE pointer to the start of the record fields in the join buffer if the there is another record to iterate over, 0 - otherwise. */ uchar *JOIN_CACHE_BKA::get_next_candidate_for_match() { if (!rem_records) return 0; rem_records--; return curr_association; } /* Check whether the matching record from the BKA cache is to be skipped SYNOPSIS skip_next_candidate_for_match rec_ptr pointer to the position in the join buffer right after the previous record DESCRIPTION This implementation of the virtual function just calls the method get_match_flag_by_pos to check whether the record referenced by ref_ptr has its match flag set to MATCH_FOUND. RETURN VALUE TRUE the record referenced by rec_ptr has its match flag set to MATCH_FOUND FALSE otherwise */ bool JOIN_CACHE_BKA::skip_next_candidate_for_match(uchar *rec_ptr) { return join_tab->check_only_first_match() && (get_match_flag_by_pos(rec_ptr) == MATCH_FOUND); } /* Read the next record from the BKA join cache buffer when looking for matches SYNOPSIS read_next_candidate_for_match rec_ptr pointer to the position in the join buffer right after the previous record DESCRIPTION This implementation of the virtual method read_next_candidate_for_match calls the method get_record_by_pos to read the record referenced by rec_ptr from the join buffer into the record buffer. If this record refers to fields in the other join buffers the call of get_record_by_po ensures that these fields are read into the corresponding record buffers as well. This function is supposed to be called after a successful call of the method get_next_candidate_for_match. RETURN VALUE none */ void JOIN_CACHE_BKA::read_next_candidate_for_match(uchar *rec_ptr) { get_record_by_pos(rec_ptr); } /* Initialize the BKA join cache SYNOPSIS init DESCRIPTION The function initializes the cache structure. It is supposed to be called right after a constructor for the JOIN_CACHE_BKA. NOTES The function first constructs a companion object of the type JOIN_TAB_SCAN_MRR, then it calls the init method of the parent class. RETURN VALUE 0 initialization with buffer allocations has been succeeded 1 otherwise */ int JOIN_CACHE_BKA::init() { int res; bool check_only_first_match= join_tab->check_only_first_match(); RANGE_SEQ_IF rs_funcs= { bka_range_seq_key_info, bka_range_seq_init, bka_range_seq_next, check_only_first_match ? bka_range_seq_skip_record : 0, bka_skip_index_tuple }; DBUG_ENTER("JOIN_CACHE_BKA::init"); JOIN_TAB_SCAN_MRR *jsm; if (!(join_tab_scan= jsm= new JOIN_TAB_SCAN_MRR(join, join_tab, mrr_mode, rs_funcs))) DBUG_RETURN(1); if ((res= JOIN_CACHE::init())) DBUG_RETURN(res); if (use_emb_key) jsm->mrr_mode |= HA_MRR_MATERIALIZED_KEYS; DBUG_RETURN(0); } /* Get the key built over the next record from BKA join buffer SYNOPSIS get_next_key() key pointer to the buffer where the key value is to be placed DESCRIPTION The function reads key fields from the current record in the join buffer. and builds the key value out of these fields that will be used to access the 'join_tab' table. Some of key fields may belong to previous caches. They are accessed via record references to the record parts stored in the previous join buffers. The other key fields always are placed right after the flag fields of the record. If the key is embedded, which means that its value can be read directly from the join buffer, then *key is set to the beginning of the key in this buffer. Otherwise the key is built in the join_tab->ref->key_buff. The function returns the length of the key if it succeeds ro read it. If is assumed that the functions starts reading at the position of the record length which is provided for each records in a BKA cache. After the key is built the 'pos' value points to the first position after the current record. The function just skips the records with MATCH_IMPOSSIBLE in the match flag field if there is any. The function returns 0 if the initial position is after the beginning of the record fields for last record from the join buffer. RETURN VALUE length of the key value - if the starting value of 'pos' points to the position before the fields for the last record, 0 - otherwise. */ uint JOIN_CACHE_BKA::get_next_key(uchar ** key) { uint len; uint32 rec_len; uchar *init_pos; JOIN_CACHE *cache; start: /* Any record in a BKA cache is prepended with its length */ DBUG_ASSERT(with_length); if ((pos+size_of_rec_len) > last_rec_pos || !records) return 0; /* Read the length of the record */ rec_len= get_rec_length(pos); pos+= size_of_rec_len; init_pos= pos; /* Read a reference to the previous cache if any */ if (prev_cache) pos+= prev_cache->get_size_of_rec_offset(); curr_rec_pos= pos; /* Read all flag fields of the record */ read_flag_fields(); if (with_match_flag && (Match_flag) curr_rec_pos[0] == MATCH_IMPOSSIBLE ) { pos= init_pos+rec_len; goto start; } if (use_emb_key) { /* An embedded key is taken directly from the join buffer */ *key= pos; len= emb_key_length; } else { /* Read key arguments from previous caches if there are any such fields */ if (external_key_arg_fields) { uchar *rec_ptr= curr_rec_pos; uint key_arg_count= external_key_arg_fields; CACHE_FIELD **copy_ptr= blob_ptr-key_arg_count; for (cache= prev_cache; key_arg_count; cache= cache->prev_cache) { uint len= 0; DBUG_ASSERT(cache); rec_ptr= cache->get_rec_ref(rec_ptr); while (!cache->referenced_fields) { cache= cache->prev_cache; DBUG_ASSERT(cache); rec_ptr= cache->get_rec_ref(rec_ptr); } while (key_arg_count && cache->read_referenced_field(*copy_ptr, rec_ptr, &len)) { copy_ptr++; --key_arg_count; } } } /* Read the other key arguments from the current record. The fields for these arguments are always first in the sequence of the record's fields. */ CACHE_FIELD *copy= field_descr+flag_fields; CACHE_FIELD *copy_end= copy+local_key_arg_fields; bool blob_in_rec_buff= blob_data_is_in_rec_buff(curr_rec_pos); for ( ; copy < copy_end; copy++) read_record_field(copy, blob_in_rec_buff); /* Build the key over the fields read into the record buffers */ TABLE_REF *ref= &join_tab->ref; cp_buffer_from_ref(join->thd, join_tab->table, ref); *key= ref->key_buff; len= ref->key_length; } pos= init_pos+rec_len; return len; } /* Check the index condition of the joined table for a record from the BKA cache SYNOPSIS skip_index_tuple() range_info pointer to the record returned by MRR DESCRIPTION This function is invoked from MRR implementation to check if an index tuple matches the index condition. It is used in the case where the index condition actually depends on both columns of the used index and columns from previous tables. NOTES Accessing columns of the previous tables requires special handling with BKA. The idea of BKA is to collect record combinations in a buffer and then do a batch of ref access lookups, i.e. by the time we're doing a lookup its previous-records-combination is not in prev_table->record[0] but somewhere in the join buffer. We need to get it from there back into prev_table(s)->record[0] before we can evaluate the index condition, and that's why we need this function instead of regular IndexConditionPushdown. NOTES Possible optimization: Before we unpack the record from a previous table check if this table is used in the condition. If so then unpack the record otherwise skip the unpacking. This should be done by a special virtual method get_partial_record_by_pos(). RETURN VALUE 1 the record combination does not satisfies the index condition 0 otherwise */ bool JOIN_CACHE_BKA::skip_index_tuple(range_id_t range_info) { DBUG_ENTER("JOIN_CACHE_BKA::skip_index_tuple"); get_record_by_pos((uchar*)range_info); DBUG_RETURN(!join_tab->cache_idx_cond->val_int()); } /* Initialize retrieval of range sequence for the BKAH join algorithm SYNOPSIS bkah_range_seq_init() init_params pointer to the BKAH join cache object n_ranges the number of ranges obtained flags combination of MRR flags DESCRIPTION The function interprets init_param as a pointer to a JOIN_CACHE_BKAH object. The function prepares for an iteration over distinct join keys built over the records from the cache join buffer. NOTE This function are used only as a callback function. RETURN VALUE init_param value that is to be used as a parameter of bkah_range_seq_next() */ static range_seq_t bkah_range_seq_init(void *init_param, uint n_ranges, uint flags) { DBUG_ENTER("bkah_range_seq_init"); JOIN_CACHE_BKAH *cache= (JOIN_CACHE_BKAH *) init_param; cache->reset(0); DBUG_RETURN((range_seq_t) init_param); } /* Get the next range/key over records from the join buffer of a BKAH cache SYNOPSIS bkah_range_seq_next() seq value returned by bkah_range_seq_init() range OUT reference to the next range DESCRIPTION The function interprets seq as a pointer to a JOIN_CACHE_BKAH object. The function returns a pointer to the range descriptor for the next unique key built over records from the join buffer. NOTE This function are used only as a callback function. RETURN VALUE FALSE ok, the range structure filled with info about the next range/key TRUE no more ranges */ static bool bkah_range_seq_next(range_seq_t rseq, KEY_MULTI_RANGE *range) { DBUG_ENTER("bkah_range_seq_next"); JOIN_CACHE_BKAH *cache= (JOIN_CACHE_BKAH *) rseq; TABLE_REF *ref= &cache->join_tab->ref; key_range *start_key= &range->start_key; if ((start_key->length= cache->get_next_key((uchar **) &start_key->key))) { start_key->keypart_map= (1 << ref->key_parts) - 1; start_key->flag= HA_READ_KEY_EXACT; range->end_key= *start_key; range->end_key.flag= HA_READ_AFTER_KEY; range->ptr= (char *) cache->get_curr_key_chain(); range->range_flag= EQ_RANGE; DBUG_RETURN(0); } DBUG_RETURN(1); } /* Check whether range_info orders to skip the next record from BKAH join buffer SYNOPSIS bkah_range_seq_skip_record() seq value returned by bkah_range_seq_init() range_info information about the next range/key returned by MRR rowid [NOT USED] rowid of the record to be checked (not used) DESCRIPTION The function interprets seq as a pointer to a JOIN_CACHE_BKAH object. The function returns TRUE if the record with this range_info is to be filtered out from the stream of records returned by multi_range_read_next(). NOTE This function are used only as a callback function. RETURN VALUE 1 record with this range_info is to be filtered out from the stream of records returned by multi_range_read_next() 0 the record is to be left in the stream */ static bool bkah_range_seq_skip_record(range_seq_t rseq, range_id_t range_info, uchar *rowid) { DBUG_ENTER("bkah_range_seq_skip_record"); JOIN_CACHE_BKAH *cache= (JOIN_CACHE_BKAH *) rseq; bool res= cache->check_all_match_flags_for_key((uchar *) range_info); DBUG_RETURN(res); } /* Check if the record combination from BKAH cache matches the index condition SYNOPSIS bkah_skip_index_tuple() rseq value returned by bka_range_seq_init() range_info record chain for the next range/key returned by MRR DESCRIPTION This is wrapper for JOIN_CACHE_BKA_UNIQUE::skip_index_tuple method, see comments there. NOTE This function is used as a RANGE_SEQ_IF::skip_index_tuple callback. RETURN VALUE 0 some records from the chain satisfy the index condition 1 otherwise */ static bool bkah_skip_index_tuple(range_seq_t rseq, range_id_t range_info) { DBUG_ENTER("bka_unique_skip_index_tuple"); JOIN_CACHE_BKAH *cache= (JOIN_CACHE_BKAH *) rseq; THD *thd= cache->thd(); bool res; status_var_increment(thd->status_var.ha_icp_attempts); if (!(res= cache->skip_index_tuple(range_info))) status_var_increment(thd->status_var.ha_icp_match); DBUG_RETURN(res); } /* Prepare to read record from BKAH cache matching the current joined record SYNOPSIS prepare_look_for_matches() skip_last <-> ignore the last record in the buffer (always unused here) DESCRIPTION The function prepares to iterate over records in the join cache buffer matching the record loaded into the record buffer for join_tab when performing join operation by BKAH join algorithm. With BKAH algorithm, if association labels are used, then record loaded into the record buffer for join_tab always has a direct reference to the chain of the mathing records from the join buffer. If association labels are not used then then the chain of the matching records is obtained by the call of the get_key_chain_by_join_key function. RETURN VALUE TRUE there are no records in the buffer to iterate over FALSE otherwise */ bool JOIN_CACHE_BKAH::prepare_look_for_matches(bool skip_last) { last_matching_rec_ref_ptr= next_matching_rec_ref_ptr= 0; if (no_association && !(curr_matching_chain= get_matching_chain_by_join_key())) //psergey: added '!' return 1; last_matching_rec_ref_ptr= get_next_rec_ref(curr_matching_chain); return 0; } /* Initialize the BKAH join cache SYNOPSIS init DESCRIPTION The function initializes the cache structure. It is supposed to be called right after a constructor for the JOIN_CACHE_BKAH. NOTES The function first constructs a companion object of the type JOIN_TAB_SCAN_MRR, then it calls the init method of the parent class. RETURN VALUE 0 initialization with buffer allocations has been succeeded 1 otherwise */ int JOIN_CACHE_BKAH::init() { bool check_only_first_match= join_tab->check_only_first_match(); no_association= test(mrr_mode & HA_MRR_NO_ASSOCIATION); RANGE_SEQ_IF rs_funcs= { bka_range_seq_key_info, bkah_range_seq_init, bkah_range_seq_next, check_only_first_match && !no_association ? bkah_range_seq_skip_record : 0, bkah_skip_index_tuple }; DBUG_ENTER("JOIN_CACHE_BKAH::init"); if (!(join_tab_scan= new JOIN_TAB_SCAN_MRR(join, join_tab, mrr_mode, rs_funcs))) DBUG_RETURN(1); DBUG_RETURN(JOIN_CACHE_HASHED::init()); } /* Check the index condition of the joined table for a record from the BKA cache SYNOPSIS skip_index_tuple() range_info record chain returned by MRR DESCRIPTION See JOIN_CACHE_BKA::skip_index_tuple(). This function is the variant for use with rhe class JOIN_CACHE_BKAH. The difference from JOIN_CACHE_BKA case is that there may be multiple previous table record combinations that share the same key(MRR range). As a consequence, we need to loop through the chain of all table record combinations that match the given MRR range key range_info until we find one that satisfies the index condition. NOTE Possible optimization: Before we unpack the record from a previous table check if this table is used in the condition. If so then unpack the record otherwise skip the unpacking. This should be done by a special virtual method get_partial_record_by_pos(). RETURN VALUE 1 any record combination from the chain referred by range_info does not satisfy the index condition 0 otherwise */ bool JOIN_CACHE_BKAH::skip_index_tuple(range_id_t range_info) { uchar *last_rec_ref_ptr= get_next_rec_ref((uchar*) range_info); uchar *next_rec_ref_ptr= last_rec_ref_ptr; DBUG_ENTER("JOIN_CACHE_BKAH::skip_index_tuple"); do { next_rec_ref_ptr= get_next_rec_ref(next_rec_ref_ptr); uchar *rec_ptr= next_rec_ref_ptr + rec_fields_offset; get_record_by_pos(rec_ptr); if (join_tab->cache_idx_cond->val_int()) DBUG_RETURN(FALSE); } while(next_rec_ref_ptr != last_rec_ref_ptr); DBUG_RETURN(TRUE); }