/* 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 */ #ifdef USE_PRAGMA_INTERFACE #pragma interface /* gcc class implementation */ #endif class Protocol; struct TABLE_LIST; void item_init(void); /* Init item functions */ class Item_field; /* "Declared Type Collation" A combination of collation and its derivation. Flags for collation aggregation modes: MY_COLL_ALLOW_SUPERSET_CONV - allow conversion to a superset MY_COLL_ALLOW_COERCIBLE_CONV - allow conversion of a coercible value (i.e. constant). MY_COLL_ALLOW_CONV - allow any kind of conversion (combination of the above two) MY_COLL_DISALLOW_NONE - don't allow return DERIVATION_NONE (e.g. when aggregating for comparison) MY_COLL_CMP_CONV - combination of MY_COLL_ALLOW_CONV and MY_COLL_DISALLOW_NONE */ #define MY_COLL_ALLOW_SUPERSET_CONV 1 #define MY_COLL_ALLOW_COERCIBLE_CONV 2 #define MY_COLL_ALLOW_CONV 3 #define MY_COLL_DISALLOW_NONE 4 #define MY_COLL_CMP_CONV 7 class DTCollation { public: CHARSET_INFO *collation; enum Derivation derivation; uint repertoire; void set_repertoire_from_charset(CHARSET_INFO *cs) { repertoire= cs->state & MY_CS_PUREASCII ? MY_REPERTOIRE_ASCII : MY_REPERTOIRE_UNICODE30; } DTCollation() { collation= &my_charset_bin; derivation= DERIVATION_NONE; repertoire= MY_REPERTOIRE_UNICODE30; } DTCollation(CHARSET_INFO *collation_arg, Derivation derivation_arg) { collation= collation_arg; derivation= derivation_arg; set_repertoire_from_charset(collation_arg); } void set(DTCollation &dt) { collation= dt.collation; derivation= dt.derivation; repertoire= dt.repertoire; } void set(CHARSET_INFO *collation_arg, Derivation derivation_arg) { collation= collation_arg; derivation= derivation_arg; set_repertoire_from_charset(collation_arg); } void set(CHARSET_INFO *collation_arg, Derivation derivation_arg, uint repertoire_arg) { collation= collation_arg; derivation= derivation_arg; repertoire= repertoire_arg; } void set(CHARSET_INFO *collation_arg) { collation= collation_arg; set_repertoire_from_charset(collation_arg); } void set(Derivation derivation_arg) { derivation= derivation_arg; } bool aggregate(DTCollation &dt, uint flags= 0); bool set(DTCollation &dt1, DTCollation &dt2, uint flags= 0) { set(dt1); return aggregate(dt2, flags); } const char *derivation_name() const { switch(derivation) { case DERIVATION_IGNORABLE: return "IGNORABLE"; case DERIVATION_COERCIBLE: return "COERCIBLE"; case DERIVATION_IMPLICIT: return "IMPLICIT"; case DERIVATION_SYSCONST: return "SYSCONST"; case DERIVATION_EXPLICIT: return "EXPLICIT"; case DERIVATION_NONE: return "NONE"; default: return "UNKNOWN"; } } }; /*************************************************************************/ /* A framework to easily handle different return types for hybrid items (hybrid item is an item whose operand can be of any type, e.g. integer, real, decimal). */ struct Hybrid_type_traits; struct Hybrid_type { int64_t integer; double real; /* Use two decimal buffers interchangeably to speed up += operation which has no native support in decimal library. Hybrid_type+= arg is implemented as dec_buf[1]= dec_buf[0] + arg. The third decimal is used as a handy temporary storage. */ my_decimal dec_buf[3]; int used_dec_buf_no; /* Traits moved to a separate class to a) be able to easily change object traits in runtime b) they work as a differentiator for the union above */ const Hybrid_type_traits *traits; Hybrid_type() {} /* XXX: add traits->copy() when needed */ Hybrid_type(const Hybrid_type &rhs) :traits(rhs.traits) {} }; /* Hybryd_type_traits interface + default implementation for REAL_RESULT */ struct Hybrid_type_traits { virtual Item_result type() const { return REAL_RESULT; } virtual void fix_length_and_dec(Item *item, Item *arg) const; /* Hybrid_type operations. */ virtual void set_zero(Hybrid_type *val) const { val->real= 0.0; } virtual void add(Hybrid_type *val, Field *f) const { val->real+= f->val_real(); } virtual void div(Hybrid_type *val, uint64_t u) const { val->real/= uint64_t2double(u); } virtual int64_t val_int(Hybrid_type *val, bool unsigned_flag __attribute__((unused))) const { return (int64_t) rint(val->real); } virtual double val_real(Hybrid_type *val) const { return val->real; } virtual my_decimal *val_decimal(Hybrid_type *val, my_decimal *buf) const; virtual String *val_str(Hybrid_type *val, String *buf, uint8_t decimals) const; static const Hybrid_type_traits *instance(); Hybrid_type_traits() {} virtual ~Hybrid_type_traits() {} }; struct Hybrid_type_traits_decimal: public Hybrid_type_traits { virtual Item_result type() const { return DECIMAL_RESULT; } virtual void fix_length_and_dec(Item *arg, Item *item) const; /* Hybrid_type operations. */ virtual void set_zero(Hybrid_type *val) const; virtual void add(Hybrid_type *val, Field *f) const; virtual void div(Hybrid_type *val, uint64_t u) const; virtual int64_t val_int(Hybrid_type *val, bool unsigned_flag) const; virtual double val_real(Hybrid_type *val) const; virtual my_decimal *val_decimal(Hybrid_type *val, my_decimal *buf __attribute__((unused))) const { return &val->dec_buf[val->used_dec_buf_no]; } virtual String *val_str(Hybrid_type *val, String *buf, uint8_t decimals) const; static const Hybrid_type_traits_decimal *instance(); Hybrid_type_traits_decimal() {}; }; struct Hybrid_type_traits_integer: public Hybrid_type_traits { virtual Item_result type() const { return INT_RESULT; } virtual void fix_length_and_dec(Item *arg, Item *item) const; /* Hybrid_type operations. */ virtual void set_zero(Hybrid_type *val) const { val->integer= 0; } virtual void add(Hybrid_type *val, Field *f) const { val->integer+= f->val_int(); } virtual void div(Hybrid_type *val, uint64_t u) const { val->integer/= (int64_t) u; } virtual int64_t val_int(Hybrid_type *val, bool unsigned_flag __attribute__((unused))) const { return val->integer; } virtual double val_real(Hybrid_type *val) const { return (double) val->integer; } virtual my_decimal *val_decimal(Hybrid_type *val, my_decimal *buf __attribute__((unused))) const { int2my_decimal(E_DEC_FATAL_ERROR, val->integer, 0, &val->dec_buf[2]); return &val->dec_buf[2]; } virtual String *val_str(Hybrid_type *val, String *buf, uint8_t decimals __attribute__((unused))) const { buf->set(val->integer, &my_charset_bin); return buf;} static const Hybrid_type_traits_integer *instance(); Hybrid_type_traits_integer() {}; }; void dummy_error_processor(THD *thd, void *data); void view_error_processor(THD *thd, void *data); /* Instances of Name_resolution_context store the information necesary for name resolution of Items and other context analysis of a query made in fix_fields(). This structure is a part of SELECT_LEX, a pointer to this structure is assigned when an item is created (which happens mostly during parsing (sql_yacc.yy)), but the structure itself will be initialized after parsing is complete TODO: move subquery of INSERT ... SELECT and CREATE ... SELECT to separate SELECT_LEX which allow to remove tricks of changing this structure before and after INSERT/CREATE and its SELECT to make correct field name resolution. */ struct Name_resolution_context: Sql_alloc { /* The name resolution context to search in when an Item cannot be resolved in this context (the context of an outer select) */ Name_resolution_context *outer_context; /* List of tables used to resolve the items of this context. Usually these are tables from the FROM clause of SELECT statement. The exceptions are INSERT ... SELECT and CREATE ... SELECT statements, where SELECT subquery is not moved to a separate SELECT_LEX. For these types of statements we have to change this member dynamically to ensure correct name resolution of different parts of the statement. */ TABLE_LIST *table_list; /* In most cases the two table references below replace 'table_list' above for the purpose of name resolution. The first and last name resolution table references allow us to search only in a sub-tree of the nested join tree in a FROM clause. This is needed for NATURAL JOIN, JOIN ... USING and JOIN ... ON. */ TABLE_LIST *first_name_resolution_table; /* Last table to search in the list of leaf table references that begins with first_name_resolution_table. */ TABLE_LIST *last_name_resolution_table; /* SELECT_LEX item belong to, in case of merged VIEW it can differ from SELECT_LEX where item was created, so we can't use table_list/field_list from there */ st_select_lex *select_lex; /* Processor of errors caused during Item name resolving, now used only to hide underlying tables in errors about views (i.e. it substitute some errors for views) */ void (*error_processor)(THD *, void *); void *error_processor_data; /* When true items are resolved in this context both against the SELECT list and this->table_list. If false, items are resolved only against this->table_list. */ bool resolve_in_select_list; /* Security context of this name resolution context. It's used for views and is non-zero only if the view is defined with SQL SECURITY DEFINER. */ Security_context *security_ctx; Name_resolution_context() :outer_context(0), table_list(0), select_lex(0), error_processor_data(0), security_ctx(0) {} void init() { resolve_in_select_list= false; error_processor= &dummy_error_processor; first_name_resolution_table= NULL; last_name_resolution_table= NULL; } void resolve_in_table_list_only(TABLE_LIST *tables) { table_list= first_name_resolution_table= tables; resolve_in_select_list= false; } void process_error(THD *thd) { (*error_processor)(thd, error_processor_data); } }; /* Store and restore the current state of a name resolution context. */ class Name_resolution_context_state { private: TABLE_LIST *save_table_list; TABLE_LIST *save_first_name_resolution_table; TABLE_LIST *save_next_name_resolution_table; bool save_resolve_in_select_list; TABLE_LIST *save_next_local; public: Name_resolution_context_state() {} /* Remove gcc warning */ public: /* Save the state of a name resolution context. */ void save_state(Name_resolution_context *context, TABLE_LIST *table_list) { save_table_list= context->table_list; save_first_name_resolution_table= context->first_name_resolution_table; save_resolve_in_select_list= context->resolve_in_select_list; save_next_local= table_list->next_local; save_next_name_resolution_table= table_list->next_name_resolution_table; } /* Restore a name resolution context from saved state. */ void restore_state(Name_resolution_context *context, TABLE_LIST *table_list) { table_list->next_local= save_next_local; table_list->next_name_resolution_table= save_next_name_resolution_table; context->table_list= save_table_list; context->first_name_resolution_table= save_first_name_resolution_table; context->resolve_in_select_list= save_resolve_in_select_list; } TABLE_LIST *get_first_name_resolution_table() { return save_first_name_resolution_table; } }; /* This enum is used to report information about monotonicity of function represented by Item* tree. Monotonicity is defined only for Item* trees that represent table partitioning expressions (i.e. have no subselects/user vars/PS parameters etc etc). An Item* tree is assumed to have the same monotonicity properties as its correspoinding function F: [signed] int64_t F(field1, field2, ...) { put values of field_i into table record buffer; return item->val_int(); } NOTE At the moment function monotonicity is not well defined (and so may be incorrect) for Item trees with parameters/return types that are different from INT_RESULT, may be NULL, or are unsigned. It will be possible to address this issue once the related partitioning bugs (BUG#16002, BUG#15447, BUG#13436) are fixed. */ typedef enum monotonicity_info { NON_MONOTONIC, /* none of the below holds */ MONOTONIC_INCREASING, /* F() is unary and (x < y) => (F(x) <= F(y)) */ MONOTONIC_STRICT_INCREASING /* F() is unary and (x < y) => (F(x) < F(y)) */ } enum_monotonicity_info; /*************************************************************************/ typedef bool (Item::*Item_processor) (uchar *arg); /* Analyzer function SYNOPSIS argp in/out IN: Analysis parameter OUT: Parameter to be passed to the transformer RETURN true Invoke the transformer false Don't do it */ typedef bool (Item::*Item_analyzer) (uchar **argp); typedef Item* (Item::*Item_transformer) (uchar *arg); typedef void (*Cond_traverser) (const Item *item, void *arg); class Item { Item(const Item &); /* Prevent use of these */ void operator=(Item &); /* Cache of the result of is_expensive(). */ int8_t is_expensive_cache; virtual bool is_expensive_processor(uchar *arg __attribute__((unused))) { return 0; } public: static void *operator new(size_t size) { return sql_alloc(size); } static void *operator new(size_t size, MEM_ROOT *mem_root) { return alloc_root(mem_root, size); } static void operator delete(void *ptr __attribute__((unused)), size_t size __attribute__((unused))) { TRASH(ptr, size); } static void operator delete(void *ptr __attribute__((unused)), MEM_ROOT *mem_root __attribute__((unused))) {} enum Type {FIELD_ITEM= 0, FUNC_ITEM, SUM_FUNC_ITEM, STRING_ITEM, INT_ITEM, REAL_ITEM, NULL_ITEM, VARBIN_ITEM, COPY_STR_ITEM, FIELD_AVG_ITEM, DEFAULT_VALUE_ITEM, PROC_ITEM,COND_ITEM, REF_ITEM, FIELD_STD_ITEM, FIELD_VARIANCE_ITEM, INSERT_VALUE_ITEM, SUBSELECT_ITEM, ROW_ITEM, CACHE_ITEM, TYPE_HOLDER, PARAM_ITEM, TRIGGER_FIELD_ITEM, DECIMAL_ITEM, XPATH_NODESET, XPATH_NODESET_CMP, VIEW_FIXER_ITEM}; enum cond_result { COND_UNDEF,COND_OK,COND_TRUE,COND_FALSE }; enum traverse_order { POSTFIX, PREFIX }; /* Reuse size, only used by SP local variable assignment, otherwize 0 */ uint rsize; /* str_values's main purpose is to be used to cache the value in save_in_field */ String str_value; char * name; /* Name from select */ /* Original item name (if it was renamed)*/ char * orig_name; Item *next; uint32_t max_length; uint name_length; /* Length of name */ int8_t marker; uint8_t decimals; my_bool maybe_null; /* If item may be null */ my_bool null_value; /* if item is null */ my_bool unsigned_flag; my_bool with_sum_func; my_bool fixed; /* If item fixed with fix_fields */ my_bool is_autogenerated_name; /* indicate was name of this Item autogenerated or set by user */ DTCollation collation; my_bool with_subselect; /* If this item is a subselect or some of its arguments is or contains a subselect. Computed by fix_fields. */ Item_result cmp_context; /* Comparison context */ // alloc & destruct is done as start of select using sql_alloc Item(); /* Constructor used by Item_field, Item_ref & aggregate (sum) functions. Used for duplicating lists in processing queries with temporary tables Also it used for Item_cond_and/Item_cond_or for creating top AND/OR structure of WHERE clause to protect it of optimisation changes in prepared statements */ Item(THD *thd, Item *item); virtual ~Item() { #ifdef EXTRA_DEBUG name=0; #endif } /*lint -e1509 */ void set_name(const char *str, uint length, CHARSET_INFO *cs); void rename(char *new_name); void init_make_field(Send_field *tmp_field,enum enum_field_types type); virtual void cleanup(); virtual void make_field(Send_field *field); Field *make_string_field(TABLE *table); virtual bool fix_fields(THD *, Item **); /* Fix after some tables has been pulled out. Basically re-calculate all attributes that are dependent on the tables. */ virtual void fix_after_pullout(st_select_lex *new_parent __attribute__((unused)), Item **ref __attribute__((unused))) {}; /* should be used in case where we are sure that we do not need complete fix_fields() procedure. */ inline void quick_fix_field() { fixed= 1; } /* Function returns 1 on overflow and -1 on fatal errors */ int save_in_field_no_warnings(Field *field, bool no_conversions); virtual int save_in_field(Field *field, bool no_conversions); virtual void save_org_in_field(Field *field) { (void) save_in_field(field, 1); } virtual int save_safe_in_field(Field *field) { return save_in_field(field, 1); } virtual bool send(Protocol *protocol, String *str); virtual bool eq(const Item *, bool binary_cmp) const; virtual Item_result result_type() const { return REAL_RESULT; } virtual Item_result cast_to_int_type() const { return result_type(); } virtual enum_field_types string_field_type() const; virtual enum_field_types field_type() const; virtual enum Type type() const =0; /* Return information about function monotonicity. See comment for enum_monotonicity_info for details. This function can only be called after fix_fields() call. */ virtual enum_monotonicity_info get_monotonicity_info() const { return NON_MONOTONIC; } /* Convert "func_arg $CMP$ const" half-interval into "FUNC(func_arg) $CMP2$ const2" SYNOPSIS val_int_endpoint() left_endp false <=> The interval is "x < const" or "x <= const" true <=> The interval is "x > const" or "x >= const" incl_endp IN true <=> the comparison is '<' or '>' false <=> the comparison is '<=' or '>=' OUT The same but for the "F(x) $CMP$ F(const)" comparison DESCRIPTION This function is defined only for unary monotonic functions. The caller supplies the source half-interval x $CMP$ const The value of const is supplied implicitly as the value this item's argument, the form of $CMP$ comparison is specified through the function's arguments. The calle returns the result interval F(x) $CMP2$ F(const) passing back F(const) as the return value, and the form of $CMP2$ through the out parameter. NULL values are assumed to be comparable and be less than any non-NULL values. RETURN The output range bound, which equal to the value of val_int() - If the value of the function is NULL then the bound is the smallest possible value of INT64_MIN */ virtual int64_t val_int_endpoint(bool left_endp __attribute__((unused)), bool *incl_endp __attribute__((unused))) { assert(0); return 0; } /* valXXX methods must return NULL or 0 or 0.0 if null_value is set. */ /* Return double precision floating point representation of item. SYNOPSIS val_real() RETURN In case of NULL value return 0.0 and set null_value flag to true. If value is not null null_value flag will be reset to false. */ virtual double val_real()=0; /* Return integer representation of item. SYNOPSIS val_int() RETURN In case of NULL value return 0 and set null_value flag to true. If value is not null null_value flag will be reset to false. */ virtual int64_t val_int()=0; /* This is just a shortcut to avoid the cast. You should still use unsigned_flag to check the sign of the item. */ inline uint64_t val_uint() { return (uint64_t) val_int(); } /* Return string representation of this item object. SYNOPSIS val_str() str an allocated buffer this or any nested Item object can use to store return value of this method. NOTE Buffer passed via argument should only be used if the item itself doesn't have an own String buffer. In case when the item maintains it's own string buffer, it's preferable to return it instead to minimize number of mallocs/memcpys. The caller of this method can modify returned string, but only in case when it was allocated on heap, (is_alloced() is true). This allows the caller to efficiently use a buffer allocated by a child without having to allocate a buffer of it's own. The buffer, given to val_str() as argument, belongs to the caller and is later used by the caller at it's own choosing. A few implications from the above: - unless you return a string object which only points to your buffer but doesn't manages it you should be ready that it will be modified. - even for not allocated strings (is_alloced() == false) the caller can change charset (see Item_func_{typecast/binary}. XXX: is this a bug? - still you should try to minimize data copying and return internal object whenever possible. RETURN In case of NULL value return 0 (NULL pointer) and set null_value flag to true. If value is not null null_value flag will be reset to false. */ virtual String *val_str(String *str)=0; /* Return decimal representation of item with fixed point. SYNOPSIS val_decimal() decimal_buffer buffer which can be used by Item for returning value (but can be not) NOTE Returned value should not be changed if it is not the same which was passed via argument. RETURN Return pointer on my_decimal (it can be other then passed via argument) if value is not NULL (null_value flag will be reset to false). In case of NULL value it return 0 pointer and set null_value flag to true. */ virtual my_decimal *val_decimal(my_decimal *decimal_buffer)= 0; /* Return boolean value of item. RETURN false value is false or NULL true value is true (not equal to 0) */ virtual bool val_bool(); virtual String *val_nodeset(String*) { return 0; } /* Helper functions, see item_sum.cc */ String *val_string_from_real(String *str); String *val_string_from_int(String *str); String *val_string_from_decimal(String *str); my_decimal *val_decimal_from_real(my_decimal *decimal_value); my_decimal *val_decimal_from_int(my_decimal *decimal_value); my_decimal *val_decimal_from_string(my_decimal *decimal_value); my_decimal *val_decimal_from_date(my_decimal *decimal_value); my_decimal *val_decimal_from_time(my_decimal *decimal_value); int64_t val_int_from_decimal(); double val_real_from_decimal(); int save_time_in_field(Field *field); int save_date_in_field(Field *field); int save_str_value_in_field(Field *field, String *result); virtual Field *get_tmp_table_field(void) { return 0; } /* This is also used to create fields in CREATE ... SELECT: */ virtual Field *tmp_table_field(TABLE *t_arg __attribute__((unused))) { return 0; } virtual const char *full_name(void) const { return name ? name : "???"; } /* *result* family of methods is analog of *val* family (see above) but return value of result_field of item if it is present. If Item have not result field, it return val(). This methods set null_value flag in same way as *val* methods do it. */ virtual double val_result() { return val_real(); } virtual int64_t val_int_result() { return val_int(); } virtual String *str_result(String* tmp) { return val_str(tmp); } virtual my_decimal *val_decimal_result(my_decimal *val) { return val_decimal(val); } virtual bool val_bool_result() { return val_bool(); } /* bit map of tables used by item */ virtual table_map used_tables() const { return (table_map) 0L; } /* Return table map of tables that can't be NULL tables (tables that are used in a context where if they would contain a NULL row generated by a LEFT or RIGHT join, the item would not be true). This expression is used on WHERE item to determinate if a LEFT JOIN can be converted to a normal join. Generally this function should return used_tables() if the function would return null if any of the arguments are null As this is only used in the beginning of optimization, the value don't have to be updated in update_used_tables() */ virtual table_map not_null_tables() const { return used_tables(); } /* Returns true if this is a simple constant item like an integer, not a constant expression. Used in the optimizer to propagate basic constants. */ virtual bool basic_const_item() const { return 0; } /* cloning of constant items (0 if it is not const) */ virtual Item *clone_item() { return 0; } virtual cond_result eq_cmp_result() const { return COND_OK; } inline uint float_length(uint decimals_par) const { return decimals != NOT_FIXED_DEC ? (DBL_DIG+2+decimals_par) : DBL_DIG+8;} virtual uint decimal_precision() const; inline int decimal_int_part() const { return my_decimal_int_part(decimal_precision(), decimals); } /* Returns true if this is constant (during query execution, i.e. its value will not change until next fix_fields) and its value is known. */ virtual bool const_item() const { return used_tables() == 0; } /* Returns true if this is constant but its value may be not known yet. (Can be used for parameters of prep. stmts or of stored procedures.) */ virtual bool const_during_execution() const { return (used_tables() & ~PARAM_TABLE_BIT) == 0; } /** This method is used for to: - to generate a view definition query (SELECT-statement); - to generate a SQL-query for EXPLAIN EXTENDED; - to generate a SQL-query to be shown in INFORMATION_SCHEMA; - debug. For more information about view definition query, INFORMATION_SCHEMA query and why they should be generated from the Item-tree, @see mysql_register_view(). */ virtual inline void print(String *str, enum_query_type query_type __attribute__((unused))) { str->append(full_name()); } void print_item_w_name(String *, enum_query_type query_type); virtual void update_used_tables() {} virtual void split_sum_func(THD *thd __attribute__((unused)), Item **ref_pointer_array __attribute__((unused)), List &fields __attribute__((unused))) {} /* Called for items that really have to be split */ void split_sum_func2(THD *thd, Item **ref_pointer_array, List &fields, Item **ref, bool skip_registered); virtual bool get_date(DRIZZLE_TIME *ltime,uint fuzzydate); virtual bool get_time(DRIZZLE_TIME *ltime); virtual bool get_date_result(DRIZZLE_TIME *ltime,uint fuzzydate) { return get_date(ltime,fuzzydate); } /* The method allows to determine nullness of a complex expression without fully evaluating it, instead of calling val/result*() then checking null_value. Used in Item_func_isnull/Item_func_isnotnull and Item_sum_count/Item_sum_count_distinct. Any new item which can be NULL must implement this method. */ virtual bool is_null() { return 0; } /* Make sure the null_value member has a correct value. */ virtual void update_null_value () { (void) val_int(); } /* Inform the item that there will be no distinction between its result being false or NULL. NOTE This function will be called for eg. Items that are top-level AND-parts of the WHERE clause. Items implementing this function (currently Item_cond_and and subquery-related item) enable special optimizations when they are "top level". */ virtual void top_level_item(void) {} /* set field of temporary table for Item which can be switched on temporary table during query processing (grouping and so on) */ virtual void set_result_field(Field *field __attribute__((unused))) {} virtual bool is_result_field(void) { return 0; } virtual bool is_bool_func(void) { return 0; } virtual void save_in_result_field(bool no_conversions __attribute__((unused))) {} /* set value of aggregate function in case of no rows for grouping were found */ virtual void no_rows_in_result(void) {} virtual Item *copy_or_same(THD *thd __attribute__((unused))) { return this; } virtual Item *copy_andor_structure(THD *thd __attribute__((unused))) { return this; } virtual Item *real_item(void) { return this; } virtual Item *get_tmp_table_item(THD *thd) { return copy_or_same(thd); } static CHARSET_INFO *default_charset(); virtual CHARSET_INFO *compare_collation() { return NULL; } virtual bool walk(Item_processor processor __attribute__((unused)), bool walk_subquery __attribute__((unused)), uchar *arg) { return (this->*processor)(arg); } virtual Item* transform(Item_transformer transformer, uchar *arg); /* This function performs a generic "compilation" of the Item tree. The process of compilation is assumed to go as follows: compile() { if (this->*some_analyzer(...)) { compile children if any; this->*some_transformer(...); } } i.e. analysis is performed top-down while transformation is done bottom-up. */ virtual Item* compile(Item_analyzer analyzer, uchar **arg_p, Item_transformer transformer, uchar *arg_t) { if ((this->*analyzer) (arg_p)) return ((this->*transformer) (arg_t)); return 0; } virtual void traverse_cond(Cond_traverser traverser __attribute__((unused)), void *arg, traverse_order order __attribute__((unused))) { (*traverser)(this, arg); } virtual bool remove_dependence_processor(uchar * arg __attribute__((unused))) { return 0; } virtual bool remove_fixed(uchar * arg __attribute__((unused))) { fixed= 0; return 0; } virtual bool cleanup_processor(uchar *arg __attribute__((unused))); virtual bool collect_item_field_processor(uchar * arg __attribute__((unused))) { return 0; } virtual bool find_item_in_field_list_processor(uchar *arg __attribute__((unused))) { return 0; } virtual bool change_context_processor(uchar *context __attribute__((unused))) { return 0; } virtual bool reset_query_id_processor(uchar *query_id_arg __attribute__((unused))) { return 0; } virtual bool register_field_in_read_map(uchar *arg __attribute__((unused))) { return 0; } virtual bool subst_argument_checker(uchar **arg) { if (*arg) *arg= NULL; return true; } virtual Item *equal_fields_propagator(uchar * arg __attribute__((unused))) { return this; } virtual bool set_no_const_sub(uchar *arg __attribute__((unused))) { return false; } virtual Item *replace_equal_field(uchar * arg __attribute__((unused))) { return this; } /* For SP local variable returns pointer to Item representing its current value and pointer to current Item otherwise. */ virtual Item *this_item(void) { return this; } virtual const Item *this_item(void) const { return this; } /* For SP local variable returns address of pointer to Item representing its current value and pointer passed via parameter otherwise. */ virtual Item **this_item_addr(THD *thd __attribute__((unused)), Item **addr_arg) { return addr_arg; } // Row emulation virtual uint cols() { return 1; } virtual Item* element_index(uint i __attribute__((unused))) { return this; } virtual Item** addr(uint i __attribute__((unused))) { return 0; } virtual bool check_cols(uint c); // It is not row => null inside is impossible virtual bool null_inside() { return 0; } // used in row subselects to get value of elements virtual void bring_value() {} Field *tmp_table_field_from_field_type(TABLE *table, bool fixed_length); virtual Item_field *filed_for_view_update() { return 0; } virtual Item *neg_transformer(THD *thd __attribute__((unused))) { return NULL; } virtual Item *update_value_transformer(uchar *select_arg __attribute__((unused))) { return this; } virtual Item *safe_charset_converter(CHARSET_INFO *tocs); void delete_self() { cleanup(); delete this; } /* result_as_int64_t() must return true for Items representing DATE/TIME functions and DATE/TIME table fields. Those Items have result_type()==STRING_RESULT (and not INT_RESULT), but their values should be compared as integers (because the integer representation is more precise than the string one). */ virtual bool result_as_int64_t() { return false; } bool is_datetime(); /* Test whether an expression is expensive to compute. Used during optimization to avoid computing expensive expressions during this phase. Also used to force temp tables when sorting on expensive functions. TODO: Normally we should have a method: cost Item::execution_cost(), where 'cost' is either 'double' or some structure of various cost parameters. */ virtual bool is_expensive() { if (is_expensive_cache < 0) is_expensive_cache= walk(&Item::is_expensive_processor, 0, (uchar*)0); return test(is_expensive_cache); } String *check_well_formed_result(String *str, bool send_error= 0); bool eq_by_collation(Item *item, bool binary_cmp, CHARSET_INFO *cs); }; class Item_basic_constant :public Item { public: /* to prevent drop fixed flag (no need parent cleanup call) */ void cleanup() { /* Restore the original field name as it might not have been allocated in the statement memory. If the name is auto generated, it must be done again between subsequent executions of a prepared statement. */ if (orig_name) name= orig_name; } }; bool agg_item_collations(DTCollation &c, const char *name, Item **items, uint nitems, uint flags, int item_sep); bool agg_item_collations_for_comparison(DTCollation &c, const char *name, Item **items, uint nitems, uint flags); bool agg_item_charsets(DTCollation &c, const char *name, Item **items, uint nitems, uint flags, int item_sep); class Item_num: public Item_basic_constant { public: Item_num() {} /* Remove gcc warning */ virtual Item_num *neg()= 0; Item *safe_charset_converter(CHARSET_INFO *tocs); }; #define NO_CACHED_FIELD_INDEX ((uint)(-1)) class st_select_lex; class Item_ident :public Item { protected: /* We have to store initial values of db_name, table_name and field_name to be able to restore them during cleanup() because they can be updated during fix_fields() to values from Field object and life-time of those is shorter than life-time of Item_field. */ const char *orig_db_name; const char *orig_table_name; const char *orig_field_name; public: Name_resolution_context *context; const char *db_name; const char *table_name; const char *field_name; bool alias_name_used; /* true if item was resolved against alias */ /* Cached value of index for this field in table->field array, used by prep. stmts for speeding up their re-execution. Holds NO_CACHED_FIELD_INDEX if index value is not known. */ uint cached_field_index; /* Cached pointer to table which contains this field, used for the same reason by prep. stmt. too in case then we have not-fully qualified field. 0 - means no cached value. */ TABLE_LIST *cached_table; st_select_lex *depended_from; Item_ident(Name_resolution_context *context_arg, const char *db_name_arg, const char *table_name_arg, const char *field_name_arg); Item_ident(THD *thd, Item_ident *item); const char *full_name() const; void cleanup(); bool remove_dependence_processor(uchar * arg); virtual void print(String *str, enum_query_type query_type); virtual bool change_context_processor(uchar *cntx) { context= (Name_resolution_context *)cntx; return false; } friend bool insert_fields(THD *thd, Name_resolution_context *context, const char *db_name, const char *table_name, List_iterator *it, bool any_privileges); }; class Item_ident_for_show :public Item { public: Field *field; const char *db_name; const char *table_name; Item_ident_for_show(Field *par_field, const char *db_arg, const char *table_name_arg) :field(par_field), db_name(db_arg), table_name(table_name_arg) {} enum Type type() const { return FIELD_ITEM; } double val_real() { return field->val_real(); } int64_t val_int() { return field->val_int(); } String *val_str(String *str) { return field->val_str(str); } my_decimal *val_decimal(my_decimal *dec) { return field->val_decimal(dec); } void make_field(Send_field *tmp_field); }; class Item_equal; class COND_EQUAL; class Item_field :public Item_ident { protected: void set_field(Field *field); public: Field *field,*result_field; Item_equal *item_equal; bool no_const_subst; /* if any_privileges set to true then here real effective privileges will be stored */ uint have_privileges; /* field need any privileges (for VIEW creation) */ bool any_privileges; Item_field(Name_resolution_context *context_arg, const char *db_arg,const char *table_name_arg, const char *field_name_arg); /* Constructor needed to process subselect with temporary tables (see Item) */ Item_field(THD *thd, Item_field *item); /* Constructor used inside setup_wild(), ensures that field, table, and database names will live as long as Item_field (this is important in prepared statements). */ Item_field(THD *thd, Name_resolution_context *context_arg, Field *field); /* If this constructor is used, fix_fields() won't work, because db_name, table_name and column_name are unknown. It's necessary to call reset_field() before fix_fields() for all fields created this way. */ Item_field(Field *field); enum Type type() const { return FIELD_ITEM; } bool eq(const Item *item, bool binary_cmp) const; double val_real(); int64_t val_int(); my_decimal *val_decimal(my_decimal *); String *val_str(String*); double val_result(); int64_t val_int_result(); String *str_result(String* tmp); my_decimal *val_decimal_result(my_decimal *); bool val_bool_result(); bool send(Protocol *protocol, String *str_arg); void reset_field(Field *f); bool fix_fields(THD *, Item **); void fix_after_pullout(st_select_lex *new_parent, Item **ref); void make_field(Send_field *tmp_field); int save_in_field(Field *field,bool no_conversions); void save_org_in_field(Field *field); table_map used_tables() const; enum Item_result result_type () const { return field->result_type(); } Item_result cast_to_int_type() const { return field->cast_to_int_type(); } enum_field_types field_type() const { return field->type(); } enum_monotonicity_info get_monotonicity_info() const { return MONOTONIC_STRICT_INCREASING; } int64_t val_int_endpoint(bool left_endp, bool *incl_endp); Field *get_tmp_table_field() { return result_field; } Field *tmp_table_field(TABLE *t_arg __attribute__((unused))) { return result_field; } bool get_date(DRIZZLE_TIME *ltime,uint fuzzydate); bool get_date_result(DRIZZLE_TIME *ltime,uint fuzzydate); bool get_time(DRIZZLE_TIME *ltime); bool is_null() { return field->is_null(); } void update_null_value(); Item *get_tmp_table_item(THD *thd); bool collect_item_field_processor(uchar * arg); bool find_item_in_field_list_processor(uchar *arg); bool register_field_in_read_map(uchar *arg); void cleanup(); bool result_as_int64_t() { return field->can_be_compared_as_int64_t(); } Item_equal *find_item_equal(COND_EQUAL *cond_equal); bool subst_argument_checker(uchar **arg); Item *equal_fields_propagator(uchar *arg); bool set_no_const_sub(uchar *arg); Item *replace_equal_field(uchar *arg); inline uint32_t max_disp_length() { return field->max_display_length(); } Item_field *filed_for_view_update() { return this; } Item *safe_charset_converter(CHARSET_INFO *tocs); int fix_outer_field(THD *thd, Field **field, Item **reference); virtual Item *update_value_transformer(uchar *select_arg); virtual void print(String *str, enum_query_type query_type); friend class Item_default_value; friend class Item_insert_value; friend class st_select_lex_unit; }; class Item_null :public Item_basic_constant { public: Item_null(char *name_par=0) { maybe_null= null_value= true; max_length= 0; name= name_par ? name_par : (char*) "NULL"; fixed= 1; collation.set(&my_charset_bin, DERIVATION_IGNORABLE); } enum Type type() const { return NULL_ITEM; } bool eq(const Item *item, bool binary_cmp) const; double val_real(); int64_t val_int(); String *val_str(String *str); my_decimal *val_decimal(my_decimal *); int save_in_field(Field *field, bool no_conversions); int save_safe_in_field(Field *field); bool send(Protocol *protocol, String *str); enum Item_result result_type () const { return STRING_RESULT; } enum_field_types field_type() const { return DRIZZLE_TYPE_NULL; } bool basic_const_item() const { return 1; } Item *clone_item() { return new Item_null(name); } bool is_null() { return 1; } virtual inline void print(String *str, enum_query_type query_type __attribute__((unused))) { str->append(STRING_WITH_LEN("NULL")); } Item *safe_charset_converter(CHARSET_INFO *tocs); }; class Item_null_result :public Item_null { public: Field *result_field; Item_null_result() : Item_null(), result_field(0) {} bool is_result_field() { return result_field != 0; } void save_in_result_field(bool no_conversions) { save_in_field(result_field, no_conversions); } }; /* Item represents one placeholder ('?') of prepared statement */ class Item_param :public Item { char cnvbuf[MAX_FIELD_WIDTH]; String cnvstr; Item *cnvitem; public: enum enum_item_param_state { NO_VALUE, NULL_VALUE, INT_VALUE, REAL_VALUE, STRING_VALUE, TIME_VALUE, LONG_DATA_VALUE, DECIMAL_VALUE } state; /* A buffer for string and long data values. Historically all allocated values returned from val_str() were treated as eligible to modification. I. e. in some cases Item_func_concat can append it's second argument to return value of the first one. Because of that we can't return the original buffer holding string data from val_str(), and have to have one buffer for data and another just pointing to the data. This is the latter one and it's returned from val_str(). Can not be declared inside the union as it's not a POD type. */ String str_value_ptr; my_decimal decimal_value; union { int64_t integer; double real; /* Character sets conversion info for string values. Character sets of client and connection defined at bind time are used for all conversions, even if one of them is later changed (i.e. between subsequent calls to mysql_stmt_execute). */ struct CONVERSION_INFO { CHARSET_INFO *character_set_client; CHARSET_INFO *character_set_of_placeholder; /* This points at character set of connection if conversion to it is required (i. e. if placeholder typecode is not BLOB). Otherwise it's equal to character_set_client (to simplify check in convert_str_value()). */ CHARSET_INFO *final_character_set_of_str_value; } cs_info; DRIZZLE_TIME time; } value; /* Cached values for virtual methods to save us one switch. */ enum Item_result item_result_type; enum Type item_type; /* Used when this item is used in a temporary table. This is NOT placeholder metadata sent to client, as this value is assigned after sending metadata (in setup_one_conversion_function). For example in case of 'SELECT ?' you'll get DRIZZLE_TYPE_STRING both in result set and placeholders metadata, no matter what type you will supply for this placeholder in mysql_stmt_execute. */ enum enum_field_types param_type; /* Offset of placeholder inside statement text. Used to create no-placeholders version of this statement for the binary log. */ uint pos_in_query; Item_param(uint pos_in_query_arg); enum Item_result result_type () const { return item_result_type; } enum Type type() const { return item_type; } enum_field_types field_type() const { return param_type; } double val_real(); int64_t val_int(); my_decimal *val_decimal(my_decimal*); String *val_str(String*); bool get_time(DRIZZLE_TIME *tm); bool get_date(DRIZZLE_TIME *tm, uint fuzzydate); int save_in_field(Field *field, bool no_conversions); void set_null(); void set_int(int64_t i, uint32_t max_length_arg); void set_double(double i); void set_decimal(const char *str, ulong length); bool set_str(const char *str, ulong length); bool set_longdata(const char *str, ulong length); void set_time(DRIZZLE_TIME *tm, timestamp_type type, uint32_t max_length_arg); bool set_from_user_var(THD *thd, const user_var_entry *entry); void reset(); /* Assign placeholder value from bind data. Note, that 'len' has different semantics in embedded library (as we don't need to check that packet is not broken there). See sql_prepare.cc for details. */ void (*set_param_func)(Item_param *param, uchar **pos, ulong len); const String *query_val_str(String *str) const; bool convert_str_value(THD *thd); /* If value for parameter was not set we treat it as non-const so noone will use parameters value in fix_fields still parameter is constant during execution. */ virtual table_map used_tables() const { return state != NO_VALUE ? (table_map)0 : PARAM_TABLE_BIT; } virtual void print(String *str, enum_query_type query_type); bool is_null() { assert(state != NO_VALUE); return state == NULL_VALUE; } bool basic_const_item() const; /* This method is used to make a copy of a basic constant item when propagating constants in the optimizer. The reason to create a new item and not use the existing one is not precisely known (2005/04/16). Probably we are trying to preserve tree structure of items, in other words, avoid pointing at one item from two different nodes of the tree. Return a new basic constant item if parameter value is a basic constant, assert otherwise. This method is called only if basic_const_item returned true. */ Item *safe_charset_converter(CHARSET_INFO *tocs); Item *clone_item(); /* Implement by-value equality evaluation if parameter value is set and is a basic constant (integer, real or string). Otherwise return false. */ bool eq(const Item *item, bool binary_cmp) const; /** Item is a argument to a limit clause. */ bool limit_clause_param; }; class Item_int :public Item_num { public: int64_t value; Item_int(int32_t i,uint length= MY_INT32_NUM_DECIMAL_DIGITS) :value((int64_t) i) { max_length=length; fixed= 1; } Item_int(int64_t i,uint length= MY_INT64_NUM_DECIMAL_DIGITS) :value(i) { max_length=length; fixed= 1; } Item_int(uint64_t i, uint length= MY_INT64_NUM_DECIMAL_DIGITS) :value((int64_t)i) { max_length=length; fixed= 1; unsigned_flag= 1; } Item_int(const char *str_arg,int64_t i,uint length) :value(i) { max_length=length; name=(char*) str_arg; fixed= 1; } Item_int(const char *str_arg, uint length=64); enum Type type() const { return INT_ITEM; } enum Item_result result_type () const { return INT_RESULT; } enum_field_types field_type() const { return DRIZZLE_TYPE_LONGLONG; } int64_t val_int() { assert(fixed == 1); return value; } double val_real() { assert(fixed == 1); return (double) value; } my_decimal *val_decimal(my_decimal *); String *val_str(String*); int save_in_field(Field *field, bool no_conversions); bool basic_const_item() const { return 1; } Item *clone_item() { return new Item_int(name,value,max_length); } virtual void print(String *str, enum_query_type query_type); Item_num *neg() { value= -value; return this; } uint decimal_precision() const { return (uint)(max_length - test(value < 0)); } bool eq(const Item *, bool binary_cmp) const; }; class Item_uint :public Item_int { public: Item_uint(const char *str_arg, uint length); Item_uint(uint64_t i) :Item_int((uint64_t) i, 10) {} Item_uint(const char *str_arg, int64_t i, uint length); double val_real() { assert(fixed == 1); return uint64_t2double((uint64_t)value); } String *val_str(String*); Item *clone_item() { return new Item_uint(name, value, max_length); } int save_in_field(Field *field, bool no_conversions); virtual void print(String *str, enum_query_type query_type); Item_num *neg (); uint decimal_precision() const { return max_length; } }; /* decimal (fixed point) constant */ class Item_decimal :public Item_num { protected: my_decimal decimal_value; public: Item_decimal(const char *str_arg, uint length, CHARSET_INFO *charset); Item_decimal(const char *str, const my_decimal *val_arg, uint decimal_par, uint length); Item_decimal(my_decimal *value_par); Item_decimal(int64_t val, bool unsig); Item_decimal(double val, int precision, int scale); Item_decimal(const uchar *bin, int precision, int scale); enum Type type() const { return DECIMAL_ITEM; } enum Item_result result_type () const { return DECIMAL_RESULT; } enum_field_types field_type() const { return DRIZZLE_TYPE_NEWDECIMAL; } int64_t val_int(); double val_real(); String *val_str(String*); my_decimal *val_decimal(my_decimal *val __attribute__((unused))) { return &decimal_value; } int save_in_field(Field *field, bool no_conversions); bool basic_const_item() const { return 1; } Item *clone_item() { return new Item_decimal(name, &decimal_value, decimals, max_length); } virtual void print(String *str, enum_query_type query_type); Item_num *neg() { my_decimal_neg(&decimal_value); unsigned_flag= !decimal_value.sign(); return this; } uint decimal_precision() const { return decimal_value.precision(); } bool eq(const Item *, bool binary_cmp) const; void set_decimal_value(my_decimal *value_par); }; class Item_float :public Item_num { char *presentation; public: double value; // Item_real() :value(0) {} Item_float(const char *str_arg, uint length); Item_float(const char *str,double val_arg,uint decimal_par,uint length) :value(val_arg) { presentation= name=(char*) str; decimals=(uint8_t) decimal_par; max_length=length; fixed= 1; } Item_float(double value_par, uint decimal_par) :presentation(0), value(value_par) { decimals= (uint8_t) decimal_par; fixed= 1; } int save_in_field(Field *field, bool no_conversions); enum Type type() const { return REAL_ITEM; } enum_field_types field_type() const { return DRIZZLE_TYPE_DOUBLE; } double val_real() { assert(fixed == 1); return value; } int64_t val_int() { assert(fixed == 1); if (value <= (double) INT64_MIN) { return INT64_MIN; } else if (value >= (double) (uint64_t) INT64_MAX) { return INT64_MAX; } return (int64_t) rint(value); } String *val_str(String*); my_decimal *val_decimal(my_decimal *); bool basic_const_item() const { return 1; } Item *clone_item() { return new Item_float(name, value, decimals, max_length); } Item_num *neg() { value= -value; return this; } virtual void print(String *str, enum_query_type query_type); bool eq(const Item *, bool binary_cmp) const; }; class Item_static_float_func :public Item_float { const char *func_name; public: Item_static_float_func(const char *str, double val_arg, uint decimal_par, uint length) :Item_float(NullS, val_arg, decimal_par, length), func_name(str) {} virtual inline void print(String *str, enum_query_type query_type __attribute__((unused))) { str->append(func_name); } Item *safe_charset_converter(CHARSET_INFO *tocs); }; class Item_string :public Item_basic_constant { public: Item_string(const char *str,uint length, CHARSET_INFO *cs, Derivation dv= DERIVATION_COERCIBLE, uint repertoire= MY_REPERTOIRE_UNICODE30) : m_cs_specified(false) { str_value.set_or_copy_aligned(str, length, cs); collation.set(cs, dv, repertoire); /* We have to have a different max_length than 'length' here to ensure that we get the right length if we do use the item to create a new table. In this case max_length must be the maximum number of chars for a string of this type because we in Create_field:: divide the max_length with mbmaxlen). */ max_length= str_value.numchars()*cs->mbmaxlen; set_name(str, length, cs); decimals=NOT_FIXED_DEC; // it is constant => can be used without fix_fields (and frequently used) fixed= 1; } /* Just create an item and do not fill string representation */ Item_string(CHARSET_INFO *cs, Derivation dv= DERIVATION_COERCIBLE) : m_cs_specified(false) { collation.set(cs, dv); max_length= 0; set_name(NULL, 0, cs); decimals= NOT_FIXED_DEC; fixed= 1; } Item_string(const char *name_par, const char *str, uint length, CHARSET_INFO *cs, Derivation dv= DERIVATION_COERCIBLE, uint repertoire= MY_REPERTOIRE_UNICODE30) : m_cs_specified(false) { str_value.set_or_copy_aligned(str, length, cs); collation.set(cs, dv, repertoire); max_length= str_value.numchars()*cs->mbmaxlen; set_name(name_par, 0, cs); decimals=NOT_FIXED_DEC; // it is constant => can be used without fix_fields (and frequently used) fixed= 1; } /* This is used in stored procedures to avoid memory leaks and does a deep copy of its argument. */ void set_str_with_copy(const char *str_arg, uint length_arg) { str_value.copy(str_arg, length_arg, collation.collation); max_length= str_value.numchars() * collation.collation->mbmaxlen; } void set_repertoire_from_value() { collation.repertoire= my_string_repertoire(str_value.charset(), str_value.ptr(), str_value.length()); } enum Type type() const { return STRING_ITEM; } double val_real(); int64_t val_int(); String *val_str(String*) { assert(fixed == 1); return (String*) &str_value; } my_decimal *val_decimal(my_decimal *); int save_in_field(Field *field, bool no_conversions); enum Item_result result_type () const { return STRING_RESULT; } enum_field_types field_type() const { return DRIZZLE_TYPE_VARCHAR; } bool basic_const_item() const { return 1; } bool eq(const Item *item, bool binary_cmp) const; Item *clone_item() { return new Item_string(name, str_value.ptr(), str_value.length(), collation.collation); } Item *safe_charset_converter(CHARSET_INFO *tocs); inline void append(char *str, uint length) { str_value.append(str, length); max_length= str_value.numchars() * collation.collation->mbmaxlen; } virtual void print(String *str, enum_query_type query_type); /** Return true if character-set-introducer was explicitly specified in the original query for this item (text literal). This operation is to be called from Item_string::print(). The idea is that when a query is generated (re-constructed) from the Item-tree, character-set-introducers should appear only for those literals, where they were explicitly specified by the user. Otherwise, that may lead to loss collation information (character set introducers implies default collation for the literal). Basically, that makes sense only for views and hopefully will be gone one day when we start using original query as a view definition. @return This operation returns the value of m_cs_specified attribute. @retval true if character set introducer was explicitly specified in the original query. @retval false otherwise. */ inline bool is_cs_specified() const { return m_cs_specified; } /** Set the value of m_cs_specified attribute. m_cs_specified attribute shows whether character-set-introducer was explicitly specified in the original query for this text literal or not. The attribute makes sense (is used) only for views. This operation is to be called from the parser during parsing an input query. */ inline void set_cs_specified(bool cs_specified) { m_cs_specified= cs_specified; } private: bool m_cs_specified; }; class Item_static_string_func :public Item_string { const char *func_name; public: Item_static_string_func(const char *name_par, const char *str, uint length, CHARSET_INFO *cs, Derivation dv= DERIVATION_COERCIBLE) :Item_string(NullS, str, length, cs, dv), func_name(name_par) {} Item *safe_charset_converter(CHARSET_INFO *tocs); virtual inline void print(String *str, enum_query_type query_type __attribute__((unused))) { str->append(func_name); } }; /* for show tables */ class Item_return_date_time :public Item_string { enum_field_types date_time_field_type; public: Item_return_date_time(const char *name_arg, enum_field_types field_type_arg) :Item_string(name_arg, 0, &my_charset_bin), date_time_field_type(field_type_arg) { } enum_field_types field_type() const { return date_time_field_type; } }; class Item_blob :public Item_string { public: Item_blob(const char *name, uint length) : Item_string(name, length, &my_charset_bin) { max_length= length; } enum Type type() const { return TYPE_HOLDER; } enum_field_types field_type() const { return DRIZZLE_TYPE_BLOB; } }; /** Item_empty_string -- is a utility class to put an item into List which is then used in protocol.send_fields() when sending SHOW output to the client. */ class Item_empty_string :public Item_string { public: Item_empty_string(const char *header,uint length, CHARSET_INFO *cs= NULL) : Item_string("",0, cs ? cs : &my_charset_utf8_general_ci) { name=(char*) header; max_length= cs ? length * cs->mbmaxlen : length; } void make_field(Send_field *field); }; class Item_return_int :public Item_int { enum_field_types int_field_type; public: Item_return_int(const char *name_arg, uint length, enum_field_types field_type_arg, int64_t value= 0) :Item_int(name_arg, value, length), int_field_type(field_type_arg) { unsigned_flag=1; } enum_field_types field_type() const { return int_field_type; } }; class Item_hex_string: public Item_basic_constant { public: Item_hex_string() {} Item_hex_string(const char *str,uint str_length); enum Type type() const { return VARBIN_ITEM; } double val_real() { assert(fixed == 1); return (double) (uint64_t) Item_hex_string::val_int(); } int64_t val_int(); bool basic_const_item() const { return 1; } String *val_str(String*) { assert(fixed == 1); return &str_value; } my_decimal *val_decimal(my_decimal *); int save_in_field(Field *field, bool no_conversions); enum Item_result result_type () const { return STRING_RESULT; } enum Item_result cast_to_int_type() const { return INT_RESULT; } enum_field_types field_type() const { return DRIZZLE_TYPE_VARCHAR; } virtual void print(String *str, enum_query_type query_type); bool eq(const Item *item, bool binary_cmp) const; virtual Item *safe_charset_converter(CHARSET_INFO *tocs); }; class Item_bin_string: public Item_hex_string { public: Item_bin_string(const char *str,uint str_length); }; class Item_result_field :public Item /* Item with result field */ { public: Field *result_field; /* Save result here */ Item_result_field() :result_field(0) {} // Constructor used for Item_sum/Item_cond_and/or (see Item comment) Item_result_field(THD *thd, Item_result_field *item): Item(thd, item), result_field(item->result_field) {} ~Item_result_field() {} /* Required with gcc 2.95 */ Field *get_tmp_table_field() { return result_field; } Field *tmp_table_field(TABLE *t_arg __attribute__((unused))) { return result_field; } table_map used_tables() const { return 1; } virtual void fix_length_and_dec()=0; void set_result_field(Field *field) { result_field= field; } bool is_result_field() { return 1; } void save_in_result_field(bool no_conversions) { save_in_field(result_field, no_conversions); } void cleanup(); }; class Item_ref :public Item_ident { protected: void set_properties(); public: enum Ref_Type { REF, DIRECT_REF, VIEW_REF, OUTER_REF }; Field *result_field; /* Save result here */ Item **ref; Item_ref(Name_resolution_context *context_arg, const char *db_arg, const char *table_name_arg, const char *field_name_arg) :Item_ident(context_arg, db_arg, table_name_arg, field_name_arg), result_field(0), ref(0) {} /* This constructor is used in two scenarios: A) *item = NULL No initialization is performed, fix_fields() call will be necessary. B) *item points to an Item this Item_ref will refer to. This is used for GROUP BY. fix_fields() will not be called in this case, so we call set_properties to make this item "fixed". set_properties performs a subset of action Item_ref::fix_fields does, and this subset is enough for Item_ref's used in GROUP BY. TODO we probably fix a superset of problems like in BUG#6658. Check this with Bar, and if we have a more broader set of problems like this. */ Item_ref(Name_resolution_context *context_arg, Item **item, const char *table_name_arg, const char *field_name_arg, bool alias_name_used_arg= false); /* Constructor need to process subselect with temporary tables (see Item) */ Item_ref(THD *thd, Item_ref *item) :Item_ident(thd, item), result_field(item->result_field), ref(item->ref) {} enum Type type() const { return REF_ITEM; } bool eq(const Item *item, bool binary_cmp) const { Item *it= ((Item *) item)->real_item(); return ref && (*ref)->eq(it, binary_cmp); } double val_real(); int64_t val_int(); my_decimal *val_decimal(my_decimal *); bool val_bool(); String *val_str(String* tmp); bool is_null(); bool get_date(DRIZZLE_TIME *ltime,uint fuzzydate); double val_result(); int64_t val_int_result(); String *str_result(String* tmp); my_decimal *val_decimal_result(my_decimal *); bool val_bool_result(); bool send(Protocol *prot, String *tmp); void make_field(Send_field *field); bool fix_fields(THD *, Item **); void fix_after_pullout(st_select_lex *new_parent, Item **ref); int save_in_field(Field *field, bool no_conversions); void save_org_in_field(Field *field); enum Item_result result_type () const { return (*ref)->result_type(); } enum_field_types field_type() const { return (*ref)->field_type(); } Field *get_tmp_table_field() { return result_field ? result_field : (*ref)->get_tmp_table_field(); } Item *get_tmp_table_item(THD *thd); table_map used_tables() const { return depended_from ? OUTER_REF_TABLE_BIT : (*ref)->used_tables(); } void update_used_tables() { if (!depended_from) (*ref)->update_used_tables(); } table_map not_null_tables() const { return (*ref)->not_null_tables(); } void set_result_field(Field *field) { result_field= field; } bool is_result_field() { return 1; } void save_in_result_field(bool no_conversions) { (*ref)->save_in_field(result_field, no_conversions); } Item *real_item() { return ref ? (*ref)->real_item() : this; } bool walk(Item_processor processor, bool walk_subquery, uchar *arg) { return (*ref)->walk(processor, walk_subquery, arg); } virtual void print(String *str, enum_query_type query_type); bool result_as_int64_t() { return (*ref)->result_as_int64_t(); } void cleanup(); Item_field *filed_for_view_update() { return (*ref)->filed_for_view_update(); } virtual Ref_Type ref_type() { return REF; } // Row emulation: forwarding of ROW-related calls to ref uint cols() { return ref && result_type() == ROW_RESULT ? (*ref)->cols() : 1; } Item* element_index(uint i) { return ref && result_type() == ROW_RESULT ? (*ref)->element_index(i) : this; } Item** addr(uint i) { return ref && result_type() == ROW_RESULT ? (*ref)->addr(i) : 0; } bool check_cols(uint c) { return ref && result_type() == ROW_RESULT ? (*ref)->check_cols(c) : Item::check_cols(c); } bool null_inside() { return ref && result_type() == ROW_RESULT ? (*ref)->null_inside() : 0; } void bring_value() { if (ref && result_type() == ROW_RESULT) (*ref)->bring_value(); } }; /* The same as Item_ref, but get value from val_* family of method to get value of item on which it referred instead of result* family. */ class Item_direct_ref :public Item_ref { public: Item_direct_ref(Name_resolution_context *context_arg, Item **item, const char *table_name_arg, const char *field_name_arg, bool alias_name_used_arg= false) :Item_ref(context_arg, item, table_name_arg, field_name_arg, alias_name_used_arg) {} /* Constructor need to process subselect with temporary tables (see Item) */ Item_direct_ref(THD *thd, Item_direct_ref *item) : Item_ref(thd, item) {} double val_real(); int64_t val_int(); String *val_str(String* tmp); my_decimal *val_decimal(my_decimal *); bool val_bool(); bool is_null(); bool get_date(DRIZZLE_TIME *ltime,uint fuzzydate); virtual Ref_Type ref_type() { return DIRECT_REF; } }; /* Class for view fields, the same as Item_direct_ref, but call fix_fields of reference if it is not called yet */ class Item_direct_view_ref :public Item_direct_ref { public: Item_direct_view_ref(Name_resolution_context *context_arg, Item **item, const char *table_name_arg, const char *field_name_arg) :Item_direct_ref(context_arg, item, table_name_arg, field_name_arg) {} /* Constructor need to process subselect with temporary tables (see Item) */ Item_direct_view_ref(THD *thd, Item_direct_ref *item) :Item_direct_ref(thd, item) {} bool fix_fields(THD *, Item **); bool eq(const Item *item, bool binary_cmp) const; Item *get_tmp_table_item(THD *thd) { Item *item= Item_ref::get_tmp_table_item(thd); item->name= name; return item; } virtual Ref_Type ref_type() { return VIEW_REF; } }; /* Class for outer fields. An object of this class is created when the select where the outer field was resolved is a grouping one. After it has been fixed the ref field will point to either an Item_ref or an Item_direct_ref object which will be used to access the field. See also comments for the fix_inner_refs() and the Item_field::fix_outer_field() functions. */ class Item_sum; class Item_outer_ref :public Item_direct_ref { public: Item *outer_ref; /* The aggregate function under which this outer ref is used, if any. */ Item_sum *in_sum_func; /* true <=> that the outer_ref is already present in the select list of the outer select. */ bool found_in_select_list; Item_outer_ref(Name_resolution_context *context_arg, Item_field *outer_field_arg) :Item_direct_ref(context_arg, 0, outer_field_arg->table_name, outer_field_arg->field_name), outer_ref(outer_field_arg), in_sum_func(0), found_in_select_list(0) { ref= &outer_ref; set_properties(); fixed= 0; } Item_outer_ref(Name_resolution_context *context_arg, Item **item, const char *table_name_arg, const char *field_name_arg, bool alias_name_used_arg) :Item_direct_ref(context_arg, item, table_name_arg, field_name_arg, alias_name_used_arg), outer_ref(0), in_sum_func(0), found_in_select_list(1) {} void save_in_result_field(bool no_conversions __attribute__((unused))) { outer_ref->save_org_in_field(result_field); } bool fix_fields(THD *, Item **); void fix_after_pullout(st_select_lex *new_parent, Item **ref); table_map used_tables() const { return (*ref)->const_item() ? 0 : OUTER_REF_TABLE_BIT; } virtual Ref_Type ref_type() { return OUTER_REF; } }; class Item_in_subselect; /* An object of this class: - Converts val_XXX() calls to ref->val_XXX_result() calls, like Item_ref. - Sets owner->was_null=true if it has returned a NULL value from any val_XXX() function. This allows to inject an Item_ref_null_helper object into subquery and then check if the subquery has produced a row with NULL value. */ class Item_ref_null_helper: public Item_ref { protected: Item_in_subselect* owner; public: Item_ref_null_helper(Name_resolution_context *context_arg, Item_in_subselect* master, Item **item, const char *table_name_arg, const char *field_name_arg) :Item_ref(context_arg, item, table_name_arg, field_name_arg), owner(master) {} double val_real(); int64_t val_int(); String* val_str(String* s); my_decimal *val_decimal(my_decimal *); bool val_bool(); bool get_date(DRIZZLE_TIME *ltime, uint fuzzydate); virtual void print(String *str, enum_query_type query_type); /* we add RAND_TABLE_BIT to prevent moving this item from HAVING to WHERE */ table_map used_tables() const { return (depended_from ? OUTER_REF_TABLE_BIT : (*ref)->used_tables() | RAND_TABLE_BIT); } }; /* The following class is used to optimize comparing of date and bigint columns We need to save the original item ('ref') to be able to call ref->save_in_field(). This is used to create index search keys. An instance of Item_int_with_ref may have signed or unsigned integer value. */ class Item_int_with_ref :public Item_int { Item *ref; public: Item_int_with_ref(int64_t i, Item *ref_arg, my_bool unsigned_arg) : Item_int(i), ref(ref_arg) { unsigned_flag= unsigned_arg; } int save_in_field(Field *field, bool no_conversions) { return ref->save_in_field(field, no_conversions); } Item *clone_item(); virtual Item *real_item() { return ref; } }; #ifdef MYSQL_SERVER #include "item_sum.h" #include "item_func.h" #include "item_row.h" #include "item_cmpfunc.h" #include "item_strfunc.h" #include "item_timefunc.h" #include "item_subselect.h" #endif class Item_copy_string :public Item { enum enum_field_types cached_field_type; public: Item *item; Item_copy_string(Item *i) :item(i) { null_value=maybe_null=item->maybe_null; decimals=item->decimals; max_length=item->max_length; name=item->name; cached_field_type= item->field_type(); } enum Type type() const { return COPY_STR_ITEM; } enum Item_result result_type () const { return STRING_RESULT; } enum_field_types field_type() const { return cached_field_type; } double val_real() { int err_not_used; char *end_not_used; return (null_value ? 0.0 : my_strntod(str_value.charset(), (char*) str_value.ptr(), str_value.length(), &end_not_used, &err_not_used)); } int64_t val_int() { int err; return null_value ? 0LL : my_strntoll(str_value.charset(),str_value.ptr(), str_value.length(),10, (char**) 0, &err); } String *val_str(String*); my_decimal *val_decimal(my_decimal *); void make_field(Send_field *field) { item->make_field(field); } void copy(); int save_in_field(Field *field, bool no_conversions __attribute__((unused))) { return save_str_value_in_field(field, &str_value); } table_map used_tables() const { return (table_map) 1L; } bool const_item() const { return 0; } bool is_null() { return null_value; } }; class Cached_item :public Sql_alloc { public: my_bool null_value; Cached_item() :null_value(0) {} virtual bool cmp(void)=0; virtual ~Cached_item(); /*line -e1509 */ }; class Cached_item_str :public Cached_item { Item *item; String value,tmp_value; public: Cached_item_str(THD *thd, Item *arg); bool cmp(void); ~Cached_item_str(); // Deallocate String:s }; class Cached_item_real :public Cached_item { Item *item; double value; public: Cached_item_real(Item *item_par) :item(item_par),value(0.0) {} bool cmp(void); }; class Cached_item_int :public Cached_item { Item *item; int64_t value; public: Cached_item_int(Item *item_par) :item(item_par),value(0) {} bool cmp(void); }; class Cached_item_decimal :public Cached_item { Item *item; my_decimal value; public: Cached_item_decimal(Item *item_par); bool cmp(void); }; class Cached_item_field :public Cached_item { uchar *buff; Field *field; uint length; public: Cached_item_field(Field *arg_field) : field(arg_field) { field= arg_field; /* TODO: take the memory allocation below out of the constructor. */ buff= (uchar*) sql_calloc(length=field->pack_length()); } bool cmp(void); }; class Item_default_value : public Item_field { public: Item *arg; Item_default_value(Name_resolution_context *context_arg) :Item_field(context_arg, (const char *)NULL, (const char *)NULL, (const char *)NULL), arg(NULL) {} Item_default_value(Name_resolution_context *context_arg, Item *a) :Item_field(context_arg, (const char *)NULL, (const char *)NULL, (const char *)NULL), arg(a) {} enum Type type() const { return DEFAULT_VALUE_ITEM; } bool eq(const Item *item, bool binary_cmp) const; bool fix_fields(THD *, Item **); virtual void print(String *str, enum_query_type query_type); int save_in_field(Field *field_arg, bool no_conversions); table_map used_tables() const { return (table_map)0L; } bool walk(Item_processor processor, bool walk_subquery, uchar *args) { return arg->walk(processor, walk_subquery, args) || (this->*processor)(args); } Item *transform(Item_transformer transformer, uchar *args); }; /* Item_insert_value -- an implementation of VALUES() function. You can use the VALUES(col_name) function in the UPDATE clause to refer to column values from the INSERT portion of the INSERT ... UPDATE statement. In other words, VALUES(col_name) in the UPDATE clause refers to the value of col_name that would be inserted, had no duplicate-key conflict occurred. In all other places this function returns NULL. */ class Item_insert_value : public Item_field { public: Item *arg; Item_insert_value(Name_resolution_context *context_arg, Item *a) :Item_field(context_arg, (const char *)NULL, (const char *)NULL, (const char *)NULL), arg(a) {} bool eq(const Item *item, bool binary_cmp) const; bool fix_fields(THD *, Item **); virtual void print(String *str, enum_query_type query_type); int save_in_field(Field *field_arg, bool no_conversions) { return Item_field::save_in_field(field_arg, no_conversions); } /* We use RAND_TABLE_BIT to prevent Item_insert_value from being treated as a constant and precalculated before execution */ table_map used_tables() const { return RAND_TABLE_BIT; } bool walk(Item_processor processor, bool walk_subquery, uchar *args) { return arg->walk(processor, walk_subquery, args) || (this->*processor)(args); } }; class Item_cache: public Item_basic_constant { protected: Item *example; table_map used_table_map; /* Field that this object will get value from. This is set/used by index-based subquery engines to detect and remove the equality injected by IN->EXISTS transformation. For all other uses of Item_cache, cached_field doesn't matter. */ Field *cached_field; enum enum_field_types cached_field_type; public: Item_cache(): example(0), used_table_map(0), cached_field(0), cached_field_type(DRIZZLE_TYPE_VARCHAR) { fixed= 1; null_value= 1; } Item_cache(enum_field_types field_type_arg): example(0), used_table_map(0), cached_field(0), cached_field_type(field_type_arg) { fixed= 1; null_value= 1; } void set_used_tables(table_map map) { used_table_map= map; } virtual bool allocate(uint i __attribute__((unused))) { return 0; } virtual bool setup(Item *item) { example= item; max_length= item->max_length; decimals= item->decimals; collation.set(item->collation); unsigned_flag= item->unsigned_flag; if (item->type() == FIELD_ITEM) cached_field= ((Item_field *)item)->field; return 0; }; virtual void store(Item *)= 0; enum Type type() const { return CACHE_ITEM; } enum_field_types field_type() const { return cached_field_type; } static Item_cache* get_cache(const Item *item); table_map used_tables() const { return used_table_map; } virtual void keep_array() {} virtual void print(String *str, enum_query_type query_type); bool eq_def(Field *field) { return cached_field ? cached_field->eq_def (field) : false; } bool eq(const Item *item, bool binary_cmp __attribute__((unused))) const { return this == item; } }; class Item_cache_int: public Item_cache { protected: int64_t value; public: Item_cache_int(): Item_cache(), value(0) {} Item_cache_int(enum_field_types field_type_arg): Item_cache(field_type_arg), value(0) {} void store(Item *item); void store(Item *item, int64_t val_arg); double val_real() { assert(fixed == 1); return (double) value; } int64_t val_int() { assert(fixed == 1); return value; } String* val_str(String *str); my_decimal *val_decimal(my_decimal *); enum Item_result result_type() const { return INT_RESULT; } bool result_as_int64_t() { return true; } }; class Item_cache_real: public Item_cache { double value; public: Item_cache_real(): Item_cache(), value(0) {} void store(Item *item); double val_real() { assert(fixed == 1); return value; } int64_t val_int(); String* val_str(String *str); my_decimal *val_decimal(my_decimal *); enum Item_result result_type() const { return REAL_RESULT; } }; class Item_cache_decimal: public Item_cache { protected: my_decimal decimal_value; public: Item_cache_decimal(): Item_cache() {} void store(Item *item); double val_real(); int64_t val_int(); String* val_str(String *str); my_decimal *val_decimal(my_decimal *); enum Item_result result_type() const { return DECIMAL_RESULT; } }; class Item_cache_str: public Item_cache { char buffer[STRING_BUFFER_USUAL_SIZE]; String *value, value_buff; bool is_varbinary; public: Item_cache_str(const Item *item) : Item_cache(), value(0), is_varbinary(item->type() == FIELD_ITEM && ((const Item_field *) item)->field->type() == DRIZZLE_TYPE_VARCHAR && !((const Item_field *) item)->field->has_charset()) {} void store(Item *item); double val_real(); int64_t val_int(); String* val_str(String *) { assert(fixed == 1); return value; } my_decimal *val_decimal(my_decimal *); enum Item_result result_type() const { return STRING_RESULT; } CHARSET_INFO *charset() const { return value->charset(); }; int save_in_field(Field *field, bool no_conversions); }; class Item_cache_row: public Item_cache { Item_cache **values; uint item_count; bool save_array; public: Item_cache_row() :Item_cache(), values(0), item_count(2), save_array(0) {} /* 'allocate' used only in row transformer, to preallocate space for row cache. */ bool allocate(uint num); /* 'setup' is needed only by row => it not called by simple row subselect (only by IN subselect (in subselect optimizer)) */ bool setup(Item *item); void store(Item *item); void illegal_method_call(const char *); void make_field(Send_field *) { illegal_method_call((const char*)"make_field"); }; double val_real() { illegal_method_call((const char*)"val"); return 0; }; int64_t val_int() { illegal_method_call((const char*)"val_int"); return 0; }; String *val_str(String *) { illegal_method_call((const char*)"val_str"); return 0; }; my_decimal *val_decimal(my_decimal *val __attribute__((unused))) { illegal_method_call((const char*)"val_decimal"); return 0; }; enum Item_result result_type() const { return ROW_RESULT; } uint cols() { return item_count; } Item *element_index(uint i) { return values[i]; } Item **addr(uint i) { return (Item **) (values + i); } bool check_cols(uint c); bool null_inside(); void bring_value(); void keep_array() { save_array= 1; } void cleanup() { Item_cache::cleanup(); if (save_array) memset(values, 0, item_count*sizeof(Item**)); else values= 0; return; } }; /* Item_type_holder used to store type. name, length of Item for UNIONS & derived tables. Item_type_holder do not need cleanup() because its time of live limited by single SP/PS execution. */ class Item_type_holder: public Item { protected: TYPELIB *enum_set_typelib; enum_field_types fld_type; void get_full_info(Item *item); /* It is used to count decimal precision in join_types */ int prev_decimal_int_part; public: Item_type_holder(THD*, Item*); Item_result result_type() const; enum_field_types field_type() const { return fld_type; }; enum Type type() const { return TYPE_HOLDER; } double val_real(); int64_t val_int(); my_decimal *val_decimal(my_decimal *); String *val_str(String*); bool join_types(THD *thd, Item *); Field *make_field_by_type(TABLE *table); static uint32_t display_length(Item *item); static enum_field_types get_real_type(Item *); }; class st_select_lex; void mark_select_range_as_dependent(THD *thd, st_select_lex *last_select, st_select_lex *current_sel, Field *found_field, Item *found_item, Item_ident *resolved_item); extern Cached_item *new_Cached_item(THD *thd, Item *item, bool use_result_field); extern void resolve_const_item(THD *thd, Item **ref, Item *cmp_item); extern bool field_is_equal_to_item(Field *field,Item *item);