/* Copyright 2006-2008 MySQL AB, 2008 Sun Microsystems, Inc. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; version 2 of the License. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1335 USA */ #ifndef SQL_STATISTICS_H #define SQL_STATISTICS_H #include #include /* For COMPLEMENTARY_FOR_QUERIES and PREFERABLY_FOR_QUERIES they are similar to the COMPLEMENTARY and PREFERABLY respectively except that with these values we would not be collecting EITS for queries like ANALYZE TABLE t1; To collect EITS with these values, we have to use PERSISITENT FOR analyze table t1 persistent for columns (col1,col2...) index (idx1, idx2...) or analyze table t1 persistent for all */ typedef enum enum_use_stat_tables_mode { NEVER, COMPLEMENTARY, PREFERABLY, COMPLEMENTARY_FOR_QUERIES, PREFERABLY_FOR_QUERIES } Use_stat_tables_mode; typedef enum enum_histogram_type { SINGLE_PREC_HB, DOUBLE_PREC_HB, JSON_HB, INVALID_HISTOGRAM } Histogram_type; enum enum_stat_tables { TABLE_STAT, COLUMN_STAT, INDEX_STAT, }; /* These enumeration types comprise the dictionary of three statistical tables table_stat, column_stat and index_stat as they defined in ../scripts/mysql_system_tables.sql. It would be nice if the declarations of these types were generated automatically by the table definitions. */ enum enum_table_stat_col { TABLE_STAT_DB_NAME, TABLE_STAT_TABLE_NAME, TABLE_STAT_CARDINALITY, TABLE_STAT_N_FIELDS }; enum enum_column_stat_col { COLUMN_STAT_DB_NAME, COLUMN_STAT_TABLE_NAME, COLUMN_STAT_COLUMN_NAME, COLUMN_STAT_MIN_VALUE, COLUMN_STAT_MAX_VALUE, COLUMN_STAT_NULLS_RATIO, COLUMN_STAT_AVG_LENGTH, COLUMN_STAT_AVG_FREQUENCY, COLUMN_STAT_HIST_SIZE, COLUMN_STAT_HIST_TYPE, COLUMN_STAT_HISTOGRAM, COLUMN_STAT_N_FIELDS }; enum enum_index_stat_col { INDEX_STAT_DB_NAME, INDEX_STAT_TABLE_NAME, INDEX_STAT_INDEX_NAME, INDEX_STAT_PREFIX_ARITY, INDEX_STAT_AVG_FREQUENCY, INDEX_STAT_N_FIELDS }; inline Use_stat_tables_mode get_use_stat_tables_mode(THD *thd) { return (Use_stat_tables_mode) (thd->variables.use_stat_tables); } inline bool check_eits_collection_allowed(THD *thd) { return (get_use_stat_tables_mode(thd) == COMPLEMENTARY || get_use_stat_tables_mode(thd) == PREFERABLY); } inline bool check_eits_preferred(THD *thd) { return (get_use_stat_tables_mode(thd) == PREFERABLY || get_use_stat_tables_mode(thd) == PREFERABLY_FOR_QUERIES); } int read_statistics_for_tables_if_needed(THD *thd, TABLE_LIST *tables); int read_statistics_for_tables(THD *thd, TABLE_LIST *tables); int collect_statistics_for_table(THD *thd, TABLE *table); void delete_stat_values_for_table_share(TABLE_SHARE *table_share); int alloc_statistics_for_table(THD *thd, TABLE *table); void free_statistics_for_table(THD *thd, TABLE *table); int update_statistics_for_table(THD *thd, TABLE *table); int delete_statistics_for_table(THD *thd, const LEX_CSTRING *db, const LEX_CSTRING *tab); int delete_statistics_for_column(THD *thd, TABLE *tab, Field *col); int delete_statistics_for_index(THD *thd, TABLE *tab, KEY *key_info, bool ext_prefixes_only); int rename_table_in_stat_tables(THD *thd, const LEX_CSTRING *db, const LEX_CSTRING *tab, const LEX_CSTRING *new_db, const LEX_CSTRING *new_tab); int rename_column_in_stat_tables(THD *thd, TABLE *tab, Field *col, const char *new_name); void set_statistics_for_table(THD *thd, TABLE *table); double get_column_avg_frequency(Field * field); double get_column_range_cardinality(Field *field, key_range *min_endp, key_range *max_endp, uint range_flag); bool is_stat_table(const LEX_CSTRING *db, LEX_CSTRING *table); bool is_eits_usable(Field* field); class Histogram_builder; /* Common base for all histograms */ class Histogram_base { public: virtual bool parse(MEM_ROOT *mem_root, const char *db_name, const char *table_name, Field *field, Histogram_type type_arg, const char *hist_data, size_t hist_data_len)= 0; virtual void serialize(Field *to_field)= 0; virtual Histogram_type get_type()=0; virtual uint get_width()=0; /* The creation-time workflow is: * create a histogram * init_for_collection() * create_builder() * feed the data to the builder * serialize(); */ virtual void init_for_collection(MEM_ROOT *mem_root, Histogram_type htype_arg, ulonglong size)=0; virtual Histogram_builder *create_builder(Field *col, uint col_len, ha_rows rows)=0; /* This function checks that histograms should be usable only when 1) the level of optimizer_use_condition_selectivity > 3 */ bool is_usable(THD *thd) { return thd->variables.optimizer_use_condition_selectivity > 3; } virtual double point_selectivity(Field *field, key_range *endpoint, double avg_sel)=0; virtual double range_selectivity(Field *field, key_range *min_endp, key_range *max_endp, double avg_sel)=0; /* Legacy: return the size of the histogram on disk. This will be stored in mysql.column_stats.hist_size column. The value is not really needed as one can look at LENGTH(mysql.column_stats.histogram) directly. */ virtual uint get_size()=0; virtual ~Histogram_base()= default; Histogram_base() : owner(NULL) {} /* Memory management: a histogram may be (exclusively) "owned" by a particular thread (done for histograms that are being collected). By default, a histogram has owner==NULL and is not owned by any particular thread. */ THD *get_owner() { return owner; } void set_owner(THD *thd) { owner=thd; } private: THD *owner; }; /* A Height-balanced histogram that stores numeric fractions */ class Histogram_binary : public Histogram_base { private: Histogram_type type; uint8 size; /* Size of values array, in bytes */ uchar *values; uint prec_factor() { switch (type) { case SINGLE_PREC_HB: return ((uint) (1 << 8) - 1); case DOUBLE_PREC_HB: return ((uint) (1 << 16) - 1); default: DBUG_ASSERT(0); } return 1; } public: uint get_width() override { switch (type) { case SINGLE_PREC_HB: return size; case DOUBLE_PREC_HB: return size / 2; default: DBUG_ASSERT(0); } return 0; } private: uint get_value(uint i) { DBUG_ASSERT(i < get_width()); switch (type) { case SINGLE_PREC_HB: return (uint) (((uint8 *) values)[i]); case DOUBLE_PREC_HB: return (uint) uint2korr(values + i * 2); default: DBUG_ASSERT(0); } return 0; } /* Find the bucket which value 'pos' falls into. */ uint find_bucket(double pos, bool first) { uint val= (uint) (pos * prec_factor()); int lp= 0; int rp= get_width() - 1; int d= get_width() / 2; uint i= lp + d; for ( ; d; d= (rp - lp) / 2, i= lp + d) { if (val == get_value(i)) break; if (val < get_value(i)) rp= i; else if (val > get_value(i + 1)) lp= i + 1; else break; } if (val > get_value(i) && i < (get_width() - 1)) i++; if (val == get_value(i)) { if (first) { while(i && val == get_value(i - 1)) i--; } else { while(i + 1 < get_width() && val == get_value(i + 1)) i++; } } return i; } public: uint get_size() override {return (uint)size;} Histogram_type get_type() override { return type; } bool parse(MEM_ROOT *mem_root, const char*, const char*, Field*, Histogram_type type_arg, const char *hist_data, size_t hist_data_len) override; void serialize(Field *to_field) override; void init_for_collection(MEM_ROOT *mem_root, Histogram_type htype_arg, ulonglong size) override; Histogram_builder *create_builder(Field *col, uint col_len, ha_rows rows) override; void set_value(uint i, double val) { switch (type) { case SINGLE_PREC_HB: ((uint8 *) values)[i]= (uint8) (val * prec_factor()); return; case DOUBLE_PREC_HB: int2store(values + i * 2, val * prec_factor()); return; default: DBUG_ASSERT(0); return; } } void set_prev_value(uint i) { switch (type) { case SINGLE_PREC_HB: ((uint8 *) values)[i]= ((uint8 *) values)[i-1]; return; case DOUBLE_PREC_HB: int2store(values + i * 2, uint2korr(values + i * 2 - 2)); return; default: DBUG_ASSERT(0); return; } } double range_selectivity(Field *field, key_range *min_endp, key_range *max_endp, double avg_sel) override; /* Estimate selectivity of "col=const" using a histogram */ double point_selectivity(Field *field, key_range *endpoint, double avg_sel) override; }; /* This is used to collect the the basic statistics from a Unique object: - count of values - count of distinct values - count of distinct values that have occurred only once */ class Basic_stats_collector { ulonglong count; /* number of values retrieved */ ulonglong count_distinct; /* number of distinct values retrieved */ /* number of distinct values that occurred only once */ ulonglong count_distinct_single_occurence; public: Basic_stats_collector() { count= 0; count_distinct= 0; count_distinct_single_occurence= 0; } ulonglong get_count_distinct() const { return count_distinct; } ulonglong get_count_single_occurence() const { return count_distinct_single_occurence; } ulonglong get_count() const { return count; } void next(void *elem, element_count elem_cnt) { count_distinct++; if (elem_cnt == 1) count_distinct_single_occurence++; count+= elem_cnt; } }; /* Histogram_builder is a helper class that is used to build histograms for columns. Do not create directly, call Histogram->get_builder(...); */ class Histogram_builder { protected: Field *column; /* table field for which the histogram is built */ uint col_length; /* size of this field */ ha_rows records; /* number of records the histogram is built for */ Histogram_builder(Field *col, uint col_len, ha_rows rows) : column(col), col_length(col_len), records(rows) {} public: // A histogram builder will also collect the counters Basic_stats_collector counters; virtual int next(void *elem, element_count elem_cnt)=0; virtual void finalize()=0; virtual ~Histogram_builder(){} }; class Columns_statistics; class Index_statistics; /* Statistical data on a table */ class Table_statistics { public: my_bool cardinality_is_null; /* TRUE if the cardinality is unknown */ ha_rows cardinality; /* Number of rows in the table */ uchar *min_max_record_buffers; /* Record buffers for min/max values */ Column_statistics *column_stats; /* Array of statistical data for columns */ Index_statistics *index_stats; /* Array of statistical data for indexes */ /* Array of records per key for index prefixes */ ulonglong *idx_avg_frequency; }; /* Statistical data on a column Note: objects of this class may be "empty", where they have almost all fields as zeros, for example, get_avg_frequency() will return 0. objects are allocated in alloc_statistics_for_table[_share]. */ class Column_statistics { private: static const uint Scale_factor_nulls_ratio= 100000; static const uint Scale_factor_avg_length= 100000; static const uint Scale_factor_avg_frequency= 100000; public: /* Bitmap indicating what statistical characteristics are available for the column */ uint32 column_stat_nulls; /* For the below two, see comments in get_column_range_cardinality() */ /* Minimum value for the column */ Field *min_value; /* Maximum value for the column */ Field *max_value; private: /* The ratio Z/N multiplied by the scale factor Scale_factor_nulls_ratio, where N is the total number of rows, Z is the number of nulls in the column */ ulong nulls_ratio; /* Average number of bytes occupied by the representation of a value of the column in memory buffers such as join buffer multiplied by the scale factor Scale_factor_avg_length. CHAR values are stripped of trailing spaces. Flexible values are stripped of their length prefixes. */ ulonglong avg_length; /* The ratio N/D multiplied by the scale factor Scale_factor_avg_frequency, where N is the number of rows with not null value in the column, D the number of distinct values among them */ ulonglong avg_frequency; public: /* Histogram type as specified in mysql.column_stats.hist_type */ Histogram_type histogram_type_on_disk; Histogram_base *histogram; uint32 no_values_provided_bitmap() { return ((1 << (COLUMN_STAT_HISTOGRAM-COLUMN_STAT_COLUMN_NAME))-1) << (COLUMN_STAT_COLUMN_NAME+1); } void set_all_nulls() { column_stat_nulls= no_values_provided_bitmap(); } void set_not_null(uint stat_field_no) { column_stat_nulls&= ~(1 << stat_field_no); } bool is_null(uint stat_field_no) { return MY_TEST(column_stat_nulls & (1 << stat_field_no)); } double get_nulls_ratio() { return (double) nulls_ratio / Scale_factor_nulls_ratio; } double get_avg_length() { return (double) avg_length / Scale_factor_avg_length; } double get_avg_frequency() { return (double) avg_frequency / Scale_factor_avg_frequency; } void set_nulls_ratio (double val) { nulls_ratio= (ulong) (val * Scale_factor_nulls_ratio); } void set_avg_length (double val) { avg_length= (ulonglong) (val * Scale_factor_avg_length); } void set_avg_frequency (double val) { avg_frequency= (ulonglong) (val * Scale_factor_avg_frequency); } bool min_max_values_are_provided() { return !is_null(COLUMN_STAT_MIN_VALUE) && !is_null(COLUMN_STAT_MAX_VALUE); } /* This function checks whether the values for the fields of the statistical tables that were NULL by DEFAULT for a column have changed or not. @retval TRUE: Statistics are not present for a column FALSE: Statisitics are present for a column */ bool no_stat_values_provided() { if (column_stat_nulls == no_values_provided_bitmap()) return true; return false; } }; /* Statistical data on an index prefixes */ class Index_statistics { private: static const uint Scale_factor_avg_frequency= 100000; /* The k-th element of this array contains the ratio N/D multiplied by the scale factor Scale_factor_avg_frequency, where N is the number of index entries without nulls in the first k components, and D is the number of distinct k-component prefixes among them */ ulonglong *avg_frequency; public: void init_avg_frequency(ulonglong *ptr) { avg_frequency= ptr; } bool avg_frequency_is_inited() { return avg_frequency != NULL; } double get_avg_frequency(uint i) { return (double) avg_frequency[i] / Scale_factor_avg_frequency; } void set_avg_frequency(uint i, double val) { avg_frequency[i]= (ulonglong) (val * Scale_factor_avg_frequency); } }; #endif /* SQL_STATISTICS_H */