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Diffstat (limited to 'sql/opt_range_mrr.cc')
| -rw-r--r-- | sql/opt_range_mrr.cc | 409 |
1 files changed, 409 insertions, 0 deletions
diff --git a/sql/opt_range_mrr.cc b/sql/opt_range_mrr.cc new file mode 100644 index 00000000..20413f5d --- /dev/null +++ b/sql/opt_range_mrr.cc @@ -0,0 +1,409 @@ +/* + Copyright (c) 2009, 2011, Monty Program 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335 USA */ + +/**************************************************************************** + MRR Range Sequence Interface implementation that walks a SEL_ARG* tree. + ****************************************************************************/ + +/* MRR range sequence, SEL_ARG* implementation: stack entry */ +typedef struct st_range_seq_entry +{ + /* + Pointers in min and max keys. They point to right-after-end of key + images. The 0-th entry has these pointing to key tuple start. + */ + uchar *min_key, *max_key; + + /* + Flags, for {keypart0, keypart1, ... this_keypart} subtuple. + min_key_flag may have NULL_RANGE set. + */ + uint min_key_flag, max_key_flag; + + /* Number of key parts */ + uint min_key_parts, max_key_parts; + SEL_ARG *key_tree; +} RANGE_SEQ_ENTRY; + + +/* + MRR range sequence, SEL_ARG* implementation: SEL_ARG graph traversal context +*/ +typedef struct st_sel_arg_range_seq +{ + uint keyno; /* index of used tree in SEL_TREE structure */ + uint real_keyno; /* Number of the index in tables */ + PARAM *param; + SEL_ARG *start; /* Root node of the traversed SEL_ARG* graph */ + + RANGE_SEQ_ENTRY stack[MAX_REF_PARTS]; + int i; /* Index of last used element in the above array */ + + bool at_start; /* TRUE <=> The traversal has just started */ + /* + Iteration functions will set this to FALSE + if ranges being traversed do not allow to construct a ROR-scan" + */ + bool is_ror_scan; +} SEL_ARG_RANGE_SEQ; + + +/* + Range sequence interface, SEL_ARG* implementation: Initialize the traversal + + SYNOPSIS + init() + init_params SEL_ARG tree traversal context + n_ranges [ignored] The number of ranges obtained + flags [ignored] HA_MRR_SINGLE_POINT, HA_MRR_FIXED_KEY + + RETURN + Value of init_param +*/ + +range_seq_t sel_arg_range_seq_init(void *init_param, uint n_ranges, uint flags) +{ + SEL_ARG_RANGE_SEQ *seq= (SEL_ARG_RANGE_SEQ*)init_param; + seq->param->range_count=0; + seq->at_start= TRUE; + seq->param->max_key_parts= 0; + seq->stack[0].key_tree= NULL; + seq->stack[0].min_key= seq->param->min_key; + seq->stack[0].min_key_flag= 0; + seq->stack[0].min_key_parts= 0; + + seq->stack[0].max_key= seq->param->max_key; + seq->stack[0].max_key_flag= 0; + seq->stack[0].max_key_parts= 0; + seq->i= 0; + return init_param; +} + + +static void step_down_to(SEL_ARG_RANGE_SEQ *arg, SEL_ARG *key_tree) +{ + RANGE_SEQ_ENTRY *cur= &arg->stack[arg->i+1]; + RANGE_SEQ_ENTRY *prev= &arg->stack[arg->i]; + + cur->key_tree= key_tree; + cur->min_key= prev->min_key; + cur->max_key= prev->max_key; + cur->min_key_parts= prev->min_key_parts; + cur->max_key_parts= prev->max_key_parts; + + uint16 stor_length= arg->param->key[arg->keyno][key_tree->part].store_length; + cur->min_key_parts += key_tree->store_min(stor_length, &cur->min_key, + prev->min_key_flag); + cur->max_key_parts += key_tree->store_max(stor_length, &cur->max_key, + prev->max_key_flag); + + cur->min_key_flag= prev->min_key_flag | key_tree->min_flag; + cur->max_key_flag= prev->max_key_flag | key_tree->max_flag; + + if (key_tree->is_null_interval()) + cur->min_key_flag |= NULL_RANGE; + (arg->i)++; +} + + +/* + Range sequence interface, SEL_ARG* implementation: get the next interval + + SYNOPSIS + sel_arg_range_seq_next() + rseq Value returned from sel_arg_range_seq_init + range OUT Store information about the range here + + DESCRIPTION + This is "get_next" function for Range sequence interface implementation + for SEL_ARG* tree. + + IMPLEMENTATION + The traversal also updates those param members: + - is_ror_scan + - range_count + - max_key_part + + RETURN + FALSE Ok + TRUE No more ranges in the sequence +*/ + +#if defined(_MSC_FULL_VER) && (_MSC_FULL_VER == 160030319) +/* + Workaround Visual Studio 2010 RTM compiler backend bug, the function enters + infinite loop. + */ +#pragma optimize("g", off) +#endif + +bool sel_arg_range_seq_next(range_seq_t rseq, KEY_MULTI_RANGE *range) +{ + SEL_ARG *key_tree; + SEL_ARG_RANGE_SEQ *seq= (SEL_ARG_RANGE_SEQ*)rseq; + if (seq->at_start) + { + key_tree= seq->start; + seq->at_start= FALSE; + goto walk_up_n_right; + } + + key_tree= seq->stack[seq->i].key_tree; + /* Ok, we're at some "full tuple" position in the tree */ + + /* Step down if we can */ + if (key_tree->next && key_tree->next != &null_element) + { + //step down; (update the tuple, we'll step right and stay there) + seq->i--; + step_down_to(seq, key_tree->next); + key_tree= key_tree->next; + seq->is_ror_scan= FALSE; + goto walk_right_n_up; + } + + /* Ok, can't step down, walk left until we can step down */ + while (1) + { + if (seq->i == 1) // can't step left + return 1; + /* Step left */ + seq->i--; + key_tree= seq->stack[seq->i].key_tree; + + /* Step down if we can */ + if (key_tree->next && key_tree->next != &null_element) + { + // Step down; update the tuple + seq->i--; + step_down_to(seq, key_tree->next); + key_tree= key_tree->next; + break; + } + } + + /* + Ok, we've stepped down from the path to previous tuple. + Walk right-up while we can + */ +walk_right_n_up: + while (key_tree->next_key_part && key_tree->next_key_part != &null_element && + key_tree->next_key_part->part == key_tree->part + 1 && + key_tree->next_key_part->type == SEL_ARG::KEY_RANGE) + { + { + RANGE_SEQ_ENTRY *cur= &seq->stack[seq->i]; + size_t min_key_length= cur->min_key - seq->param->min_key; + size_t max_key_length= cur->max_key - seq->param->max_key; + size_t len= cur->min_key - cur[-1].min_key; + if (!(min_key_length == max_key_length && + !memcmp(cur[-1].min_key, cur[-1].max_key, len) && + !key_tree->min_flag && !key_tree->max_flag)) + { + seq->is_ror_scan= FALSE; + if (!key_tree->min_flag) + cur->min_key_parts += + key_tree->next_key_part->store_min_key(seq->param->key[seq->keyno], + &cur->min_key, + &cur->min_key_flag, MAX_KEY); + if (!key_tree->max_flag) + cur->max_key_parts += + key_tree->next_key_part->store_max_key(seq->param->key[seq->keyno], + &cur->max_key, + &cur->max_key_flag, MAX_KEY); + break; + } + } + + /* + Ok, current atomic interval is in form "t.field=const" and there is + next_key_part interval. Step right, and walk up from there. + */ + key_tree= key_tree->next_key_part; + +walk_up_n_right: + while (key_tree->prev && key_tree->prev != &null_element) + { + /* Step up */ + key_tree= key_tree->prev; + } + step_down_to(seq, key_tree); + } + + /* Ok got a tuple */ + RANGE_SEQ_ENTRY *cur= &seq->stack[seq->i]; + uint min_key_length= (uint)(cur->min_key - seq->param->min_key); + + range->ptr= (char*)(intptr)(key_tree->part); + uint max_key_parts; + if (cur->min_key_flag & GEOM_FLAG) + { + range->range_flag= cur->min_key_flag; + + /* Here minimum contains also function code bits, and maximum is +inf */ + range->start_key.key= seq->param->min_key; + range->start_key.length= min_key_length; + range->start_key.keypart_map= make_prev_keypart_map(cur->min_key_parts); + range->start_key.flag= (ha_rkey_function) (cur->min_key_flag ^ GEOM_FLAG); + max_key_parts= cur->min_key_parts; + } + else + { + max_key_parts= MY_MAX(cur->min_key_parts, cur->max_key_parts); + + range->start_key.key= seq->param->min_key; + range->start_key.length= (uint)(cur->min_key - seq->param->min_key); + range->start_key.keypart_map= make_prev_keypart_map(cur->min_key_parts); + range->start_key.flag= (cur->min_key_flag & NEAR_MIN ? HA_READ_AFTER_KEY : + HA_READ_KEY_EXACT); + + range->end_key.key= seq->param->max_key; + range->end_key.length= (uint)(cur->max_key - seq->param->max_key); + range->end_key.flag= (cur->max_key_flag & NEAR_MAX ? HA_READ_BEFORE_KEY : + HA_READ_AFTER_KEY); + range->end_key.keypart_map= make_prev_keypart_map(cur->max_key_parts); + + KEY *key_info; + if (seq->real_keyno== MAX_KEY) + key_info= NULL; + else + key_info= &seq->param->table->key_info[seq->real_keyno]; + + /* + This is an equality range (keypart_0=X and ... and keypart_n=Z) if + (1) - There are no flags indicating open range (e.g., + "keypart_x > y") or GIS. + (2) - The lower bound and the upper bound of the range has the + same value (min_key == max_key). + */ + const uint is_open_range = + (NO_MIN_RANGE | NO_MAX_RANGE | NEAR_MIN | NEAR_MAX | GEOM_FLAG); + const bool is_eq_range_pred = + !(cur->min_key_flag & is_open_range) && // (1) + !(cur->max_key_flag & is_open_range) && // (1) + range->start_key.length == range->end_key.length && // (2) + !memcmp(seq->param->min_key, seq->param->max_key, // (2) + range->start_key.length); + + range->range_flag= 0; + if (is_eq_range_pred) + { + range->range_flag = EQ_RANGE; + + /* + Conditions below: + (1) - Range analysis is used for estimating condition selectivity + (2) - This is a unique key, and we have conditions for all its + user-defined key parts. + (3) - The table uses extended keys, this key covers all components, + and we have conditions for all key parts. + */ + if ( + !key_info || // (1) + ((uint)key_tree->part+1 == key_info->user_defined_key_parts && // (2) + key_info->flags & HA_NOSAME) || // (2) + ((key_info->flags & HA_EXT_NOSAME) && // (3) + (uint)key_tree->part+1 == key_info->ext_key_parts) // (3) + ) + range->range_flag |= UNIQUE_RANGE | (cur->min_key_flag & NULL_RANGE); + } + + if (seq->is_ror_scan) + { + /* + If we get here, the condition on the key was converted to form + "(keyXpart1 = c1) AND ... AND (keyXpart{key_tree->part - 1} = cN) AND + somecond(keyXpart{key_tree->part})" + Check if + somecond is "keyXpart{key_tree->part} = const" and + uncovered "tail" of KeyX parts is either empty or is identical to + first members of clustered primary key. + */ + if (!(!(cur->min_key_flag & ~NULL_RANGE) && !cur->max_key_flag && + (range->start_key.length == range->end_key.length) && + !memcmp(range->start_key.key, range->end_key.key, range->start_key.length) && + is_key_scan_ror(seq->param, seq->real_keyno, key_tree->part + 1))) + seq->is_ror_scan= FALSE; + } + } + seq->param->range_count++; + seq->param->max_key_parts= MY_MAX(seq->param->max_key_parts, max_key_parts); + return 0; +} + +#if defined(_MSC_FULL_VER) && (_MSC_FULL_VER == 160030319) +/* VS2010 compiler bug workaround */ +#pragma optimize("g", on) +#endif + + +/**************************************************************************** + MRR Range Sequence Interface implementation that walks array<QUICK_RANGE> + ****************************************************************************/ + +/* + Range sequence interface implementation for array<QUICK_RANGE>: initialize + + SYNOPSIS + quick_range_seq_init() + init_param Caller-opaque paramenter: QUICK_RANGE_SELECT* pointer + n_ranges Number of ranges in the sequence (ignored) + flags MRR flags (currently not used) + + RETURN + Opaque value to be passed to quick_range_seq_next +*/ + +range_seq_t quick_range_seq_init(void *init_param, uint n_ranges, uint flags) +{ + QUICK_RANGE_SELECT *quick= (QUICK_RANGE_SELECT*)init_param; + quick->qr_traversal_ctx.first= (QUICK_RANGE**)quick->ranges.buffer; + quick->qr_traversal_ctx.cur= (QUICK_RANGE**)quick->ranges.buffer; + quick->qr_traversal_ctx.last= quick->qr_traversal_ctx.cur + + quick->ranges.elements; + return &quick->qr_traversal_ctx; +} + + +/* + Range sequence interface implementation for array<QUICK_RANGE>: get next + + SYNOPSIS + quick_range_seq_next() + rseq Value returned from quick_range_seq_init + range OUT Store information about the range here + + RETURN + 0 Ok + 1 No more ranges in the sequence +*/ + +bool quick_range_seq_next(range_seq_t rseq, KEY_MULTI_RANGE *range) +{ + QUICK_RANGE_SEQ_CTX *ctx= (QUICK_RANGE_SEQ_CTX*)rseq; + + if (ctx->cur == ctx->last) + return 1; /* no more ranges */ + + QUICK_RANGE *cur= *(ctx->cur); + cur->make_min_endpoint(&range->start_key); + cur->make_max_endpoint(&range->end_key); + range->range_flag= cur->flag; + ctx->cur++; + return 0; +} + + |