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用于EagleEye3.0 规则集漏报和误报测试的示例项目,项目收集于github和gitee
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test-example-projects/c++_projects/280w-mysql-8.0.18/sql/item_cmpfunc.h

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#ifndef ITEM_CMPFUNC_INCLUDED
#define ITEM_CMPFUNC_INCLUDED
/* Copyright (c) 2000, 2019, Oracle and/or its affiliates. All rights reserved.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License, version 2.0,
as published by the Free Software Foundation.
This program is also distributed with certain software (including
but not limited to OpenSSL) that is licensed under separate terms,
as designated in a particular file or component or in included license
documentation. The authors of MySQL hereby grant you an additional
permission to link the program and your derivative works with the
separately licensed software that they have included with MySQL.
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, version 2.0, 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 02110-1301 USA */
/* compare and test functions */
#include <string.h>
#include <sys/types.h>
#include "field_types.h"
#include "json_dom.h" // Json_wrapper
//#include "extra/regex/my_regex.h" // my_regex_t
#include "m_ctype.h"
#include "my_alloc.h"
#include "my_compiler.h"
#include "my_dbug.h"
#include "my_inttypes.h"
#include "my_sys.h"
#include "my_table_map.h"
#include "my_time.h"
#include "mysql/udf_registration_types.h"
#include "mysql_time.h"
#include "sql/enum_query_type.h"
#include "sql/item.h"
#include "sql/item_func.h" // Item_int_func
#include "sql/item_row.h" // Item_row
#include "sql/mem_root_array.h" // Mem_root_array
#include "sql/my_decimal.h"
#include "sql/parse_tree_node_base.h"
#include "sql/psi_memory_key.h" // key_memory_JSON
#include "sql/sql_const.h"
#include "sql/sql_list.h"
#include "sql/table.h"
#include "sql_string.h"
#include "template_utils.h" // down_cast
class Arg_comparator;
class Field;
class Item_func_eq;
class Item_in_subselect;
class Item_subselect;
class Item_sum_hybrid;
class Json_scalar_holder;
class Json_wrapper;
class PT_item_list;
class QEP_TAB;
class SELECT_LEX;
class THD;
struct MY_BITMAP;
Item *make_condition(Parse_context *pc, Item *item);
typedef int (Arg_comparator::*arg_cmp_func)();
/// A class that represents a join condition in a hash join. The class holds an
/// equality condition, as well as a pre-calculated bitmap of the used tables
/// (Item::used_tables()) for each side of the condition.
///
/// The class also contains one Item for each side of the condition. In most
/// cases, the Item is only a pointer to the left/right Item of the join
/// condition. But for certain data types (DECIMAL, DOUBLE(M, N), FLOAT(M, N)),
/// the Item might be a typecast. Either way, the caller should use these Items
/// when i.e. reading the values from the join condition, so that the values are
/// read in the right data type context. See the comments for
/// Item_func_eq::create_cast_if_needed for more details around this.
class HashJoinCondition {
public:
HashJoinCondition(Item_func_eq *join_condition, MEM_ROOT *mem_root);
Item_func_eq *join_condition() const { return m_join_condition; }
Item *left_extractor() const { return m_left_extractor; }
Item *right_extractor() const { return m_right_extractor; }
bool left_uses_any_table(table_map tables) const {
return (m_left_used_tables & tables) != 0;
}
bool right_uses_any_table(table_map tables) const {
return (m_right_used_tables & tables) != 0;
}
size_t max_character_length() const { return m_max_character_length; }
private:
Item_func_eq *m_join_condition;
Item *m_left_extractor;
Item *m_right_extractor;
// Item::used_tables() is heavily used during the join to determine which side
// of the condition we are to read the value from, so caching the result of
// used_tables() gives a nice speedup.
const table_map m_left_used_tables;
const table_map m_right_used_tables;
// The maximum number of characters among the two arguments. This is only
// relevant when we have a PAD SPACE collation and the SQL mode
// PAD_CHAR_TO_FULL_LENGTH enabled, since we will have to pad the shortest
// argument to the same length as the longest argument.
const size_t m_max_character_length{0};
};
class Arg_comparator {
Item **left{nullptr};
Item **right{nullptr};
arg_cmp_func func;
Item_result_field *owner;
Arg_comparator *comparators{nullptr}; // used only for compare_row()
uint16 comparator_count{0};
double precision;
/* Fields used in DATE/DATETIME comparison. */
Item *left_cache{nullptr}; // Cached values of "left" and "right" items
Item *right_cache{nullptr};
bool set_null{true}; // true <=> set owner->null_value
// when one of arguments is NULL.
bool try_year_cmp_func(Item_result type);
static bool get_date_from_const(Item *date_arg, Item *str_arg,
ulonglong *const_value);
/**
Only used by compare_json() in the case where a JSON value is
compared to an SQL value. This member points to pre-allocated
memory that can be used instead of the heap when converting the
SQL value to a JSON value.
*/
Json_scalar_holder *json_scalar{nullptr};
/**
When comparing strings, compare at most these many bytes.
A value of zero means "no limit".
*/
size_t m_max_str_length{0};
public:
DTCollation cmp_collation;
/* Allow owner function to use string buffers. */
String value1, value2;
Arg_comparator() = default;
Arg_comparator(Item **left, Item **right) : left(left), right(right) {}
bool set_compare_func(Item_result_field *owner, Item_result type);
bool set_cmp_func(Item_result_field *owner_arg, Item **left, Item **right,
Item_result type);
bool set_cmp_func(Item_result_field *owner_arg, Item **left, Item **right,
bool set_null_arg);
/**
Comparison function are expected to operate on arguments having the
same data types. Since MySQL has very loosened up rules, it accepts
all kind of arguments which the standard SQL does not allow, and then it
converts the arguments internally to ones usable in the comparison.
This function transforms these internal conversions to explicit CASTs
so that the internally executed query becomes compatible with the standard
At the moment nodes are injected only for comparisons between:
1) temporal types and numeric data types: in which case the
comparison is normally done as DOUBLE, so the arguments which are not
floating point, will get converted to DOUBLE, and also for
2) comparisons between temporal types: in which case the
comparison happens as DATETIME if the arguments have different data
types, so in this case the temporal arguments that are not DATETIME
will get wrapped in a CAST to DATETIME.
WL#12108; This function will limit itself to comparison between regular
functions, aggregation functions and fields, all of which are constant
for execution (so this excludes stored procedures, stored functions, GC,
user defined functions, as well as literals).
For const arguments, see type conversions done in fold_condition.
@return false if successful, true otherwise
*/
bool inject_cast_nodes();
/**
When comparing strings, compare at most max_length bytes.
@param max_length how much to compare
*/
void set_max_str_length(size_t max_length) { m_max_str_length = max_length; }
inline int compare() { return (this->*func)(); }
int compare_string(); // compare args[0] & args[1]
int compare_binary_string(); // compare args[0] & args[1]
int compare_real(); // compare args[0] & args[1]
int compare_decimal(); // compare args[0] & args[1]
int compare_int_signed(); // compare args[0] & args[1]
int compare_int_signed_unsigned();
int compare_int_unsigned_signed();
int compare_int_unsigned();
int compare_time_packed();
int compare_row(); // compare args[0] & args[1]
int compare_real_fixed();
int compare_datetime(); // compare args[0] & args[1] as DATETIMEs
int compare_json();
bool compare_null_values();
static bool can_compare_as_dates(Item *a, Item *b);
Item **cache_converted_constant(THD *thd, Item **value, Item **cache,
Item_result type);
void set_datetime_cmp_func(Item_result_field *owner_arg, Item **a1,
Item **b1);
static arg_cmp_func comparator_matrix[5];
void cleanup();
/*
Set correct cmp_context if items would be compared as INTs.
*/
inline void set_cmp_context_for_datetime() {
DBUG_ASSERT(func == &Arg_comparator::compare_datetime);
if ((*left)->is_temporal()) (*left)->cmp_context = INT_RESULT;
if ((*right)->is_temporal()) (*right)->cmp_context = INT_RESULT;
}
Item_result get_compare_type() const { return m_compare_type; }
/// @returns true if the class has decided that values should be extracted
/// from the Items using function pointers set up by this class.
bool use_custom_value_extractors() const {
return get_value_a_func != nullptr;
}
// Read the value from one of the Items (decided by "left_argument"), using
// the function pointers that this class has set up. This can happen for DATE,
// TIME, DATETIME and YEAR values, and the returned value is a temporal value
// in packed format.
longlong extract_value_from_argument(THD *thd, Item *item, bool left_argument,
bool *is_null) const;
private:
/// A function pointer that is used for retrieving the value from argument
/// "left". This function is only used when we are comparing in a datetime
/// context, and it retrieves the value as a DATE, TIME, DATETIME or YEAR,
/// depending on the comparison context.
///
/// @param thd thread handle. Used to retrieve the SQL mode among other things
/// @param item_arg the item to retrieve the value from
/// @param cache_arg a pointer to an Item where we can cache the value
/// from "item_arg". Can be nullptr
/// @param warn_item if rasing an conversion warning, the warning gets the
/// data type and item name from this item
/// @param is_null whether or not "item_arg" returned SQL NULL
///
/// @returns a DATE/TIME/YEAR/DATETIME value, in packed format
longlong (*get_value_a_func)(THD *thd, Item ***item_arg, Item **cache_arg,
const Item *warn_item, bool *is_null){nullptr};
// This function does the same as "get_value_a_func", except that it returns
// the value from the argument "right" (the right side of the comparison).
longlong (*get_value_b_func)(THD *thd, Item ***item_arg, Item **cache_arg,
const Item *warn_item, bool *is_null){nullptr};
// The data type that is used when comparing the two Items. I.e., if the type
// is INT_RESULT, we call val_int() on both sides and compare those.
Item_result m_compare_type{INVALID_RESULT};
};
class Item_bool_func : public Item_int_func {
public:
Item_bool_func() : Item_int_func(), m_created_by_in2exists(false) {}
explicit Item_bool_func(const POS &pos)
: Item_int_func(pos), m_created_by_in2exists(false) {}
Item_bool_func(Item *a) : Item_int_func(a), m_created_by_in2exists(false) {}
Item_bool_func(const POS &pos, Item *a)
: Item_int_func(pos, a), m_created_by_in2exists(false) {}
Item_bool_func(Item *a, Item *b)
: Item_int_func(a, b), m_created_by_in2exists(false) {}
Item_bool_func(const POS &pos, Item *a, Item *b)
: Item_int_func(pos, a, b), m_created_by_in2exists(false) {}
Item_bool_func(THD *thd, Item_bool_func *item)
: Item_int_func(thd, item),
m_created_by_in2exists(item->m_created_by_in2exists) {}
bool is_bool_func() const override { return true; }
bool resolve_type(THD *) override {
max_length = 1;
return false;
}
uint decimal_precision() const override { return 1; }
bool created_by_in2exists() const override { return m_created_by_in2exists; }
void set_created_by_in2exists() { m_created_by_in2exists = true; }
static const char *bool_transform_names[10];
/**
Array that transforms a boolean test according to another.
First dimension is existing value, second dimension is test to apply
*/
static const Bool_test bool_transform[10][8];
private:
/**
True <=> this item was added by IN->EXISTS subquery transformation, and
should thus be deleted if we switch to materialization.
*/
bool m_created_by_in2exists;
};
/**
A predicate that is "always true" or "always false". To be used as a
standalone condition or as part of conditions, together with other condition
and predicate objects.
Mostly used when generating conditions internally.
*/
class Item_func_bool_const : public Item_bool_func {
public:
Item_func_bool_const() : Item_bool_func() {
max_length = 1;
used_tables_cache = 0;
not_null_tables_cache = 0;
fixed = true;
}
explicit Item_func_bool_const(const POS &pos) : Item_bool_func(pos) {
max_length = 1;
used_tables_cache = 0;
not_null_tables_cache = 0;
fixed = true;
}
bool fix_fields(THD *, Item **) override { return false; }
bool basic_const_item() const override { return true; }
void cleanup() override {}
};
/// A predicate that is "always true".
class Item_func_true : public Item_func_bool_const {
public:
Item_func_true() : Item_func_bool_const() {}
explicit Item_func_true(const POS &pos) : Item_func_bool_const(pos) {}
const char *func_name() const override { return "true"; }
bool val_bool() override { return true; }
longlong val_int() override { return 1; }
void print(const THD *, String *str, enum_query_type) const override {
str->append("true");
}
};
/// A predicate that is "always false".
class Item_func_false : public Item_func_bool_const {
public:
Item_func_false() : Item_func_bool_const() {}
explicit Item_func_false(const POS &pos) : Item_func_bool_const(pos) {}
const char *func_name() const override { return "false"; }
bool val_bool() override { return false; }
longlong val_int() override { return 0; }
void print(const THD *, String *str, enum_query_type) const override {
str->append("false");
}
};
/**
Item class, to represent <code>X IS [NOT] (TRUE | FALSE)</code>
boolean predicates.
*/
class Item_func_truth final : public Item_bool_func {
typedef Item_bool_func super;
public:
longlong val_int() override;
bool resolve_type(THD *) override;
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
Item *truth_transformer(THD *, Bool_test test) override {
truth_test = super::bool_transform[truth_test][test];
return this;
}
const char *func_name() const override {
return super::bool_transform_names[truth_test];
}
virtual enum Functype functype() const override { return ISTRUTH_FUNC; }
Item_func_truth(const POS &pos, Item *a, Bool_test truth_test)
: super(pos, a), truth_test(truth_test) {
null_on_null = false;
switch (truth_test) {
case BOOL_IS_TRUE:
case BOOL_IS_FALSE:
case BOOL_NOT_TRUE:
case BOOL_NOT_FALSE:
break;
default:
DBUG_ASSERT(false);
}
}
Item_func_truth(Item *a, Bool_test truth_test)
: super(a), truth_test(truth_test) {
null_on_null = false;
switch (truth_test) {
case BOOL_IS_TRUE:
case BOOL_IS_FALSE:
case BOOL_NOT_TRUE:
case BOOL_NOT_FALSE:
break;
default:
DBUG_ASSERT(false);
}
}
void apply_is_true() override {
/*
This item cannot produce NULL result. But, if the upper item confuses
NULL and FALSE, we can do as if NULL input caused a NULL result when it
actually causes a FALSE result.
*/
switch (truth_test) {
case BOOL_IS_TRUE:
case BOOL_IS_FALSE:
null_on_null = true;
default:
break;
}
}
protected:
Bool_test truth_test; ///< The value we're testing for.
};
static const int UNKNOWN = -1;
/*
Item_in_optimizer(left_expr, Item_in_subselect(...))
Item_in_optimizer is used to wrap an instance of Item_in_subselect. This
class does the following:
- Evaluate the left expression and store it in Item_cache_* object (to
avoid re-evaluating it many times during subquery execution)
- Shortcut the evaluation of "NULL IN (...)" to NULL in the cases where we
don't care if the result is NULL or FALSE.
args[1] keeps a reference to the Item_in_subselect object.
args[0] is a copy of Item_in_subselect's left expression and should be
kept equal also after resolving.
NOTE
It is not quite clear why the above listed functionality should be
placed into a separate class called 'Item_in_optimizer'.
*/
class Item_in_optimizer final : public Item_bool_func {
private:
Item_cache *cache;
bool save_cache;
/*
Stores the value of "NULL IN (SELECT ...)" for uncorrelated subqueries:
UNKNOWN - "NULL in (SELECT ...)" has not yet been evaluated
FALSE - result is FALSE
TRUE - result is NULL
*/
int result_for_null_param;
public:
Item_in_optimizer(Item *a, Item_in_subselect *b)
: Item_bool_func(a, reinterpret_cast<Item *>(b)),
cache(0),
save_cache(0),
result_for_null_param(UNKNOWN) {
set_subquery();
}
bool fix_fields(THD *, Item **) override;
bool fix_left(THD *thd, Item **ref);
void fix_after_pullout(SELECT_LEX *parent_select,
SELECT_LEX *removed_select) override;
bool is_null() override;
longlong val_int() override;
void cleanup() override;
const char *func_name() const override { return "<in_optimizer>"; }
Item_cache **get_cache() { return &cache; }
void keep_top_level_cache();
Item *transform(Item_transformer transformer, uchar *arg) override;
void replace_argument(THD *thd, Item **oldpp, Item *newp) override;
};
/// Abstract factory interface for creating comparison predicates.
class Comp_creator {
public:
virtual ~Comp_creator() {}
virtual Item_bool_func *create(Item *a, Item *b) const = 0;
/// This interface is only used by Item_allany_subselect.
virtual const char *symbol(bool invert) const = 0;
virtual bool eqne_op() const = 0;
virtual bool l_op() const = 0;
};
/// Abstract base class for the comparison operators =, <> and <=>.
class Linear_comp_creator : public Comp_creator {
public:
virtual Item_bool_func *create(Item *a, Item *b) const;
virtual bool eqne_op() const { return true; }
virtual bool l_op() const { return false; }
protected:
/**
Creates only an item tree node, without attempting to rewrite row
constructors.
@see create()
*/
virtual Item_bool_func *create_scalar_predicate(Item *a, Item *b) const = 0;
/// Combines a list of conditions <code>exp op exp</code>.
virtual Item_bool_func *combine(List<Item> list) const = 0;
};
class Eq_creator : public Linear_comp_creator {
public:
virtual const char *symbol(bool invert) const { return invert ? "<>" : "="; }
protected:
virtual Item_bool_func *create_scalar_predicate(Item *a, Item *b) const;
virtual Item_bool_func *combine(List<Item> list) const;
};
class Equal_creator : public Linear_comp_creator {
public:
virtual const char *symbol(bool invert MY_ATTRIBUTE((unused))) const {
// This will never be called with true.
DBUG_ASSERT(!invert);
return "<=>";
}
protected:
virtual Item_bool_func *create_scalar_predicate(Item *a, Item *b) const;
virtual Item_bool_func *combine(List<Item> list) const;
};
class Ne_creator : public Linear_comp_creator {
public:
virtual const char *symbol(bool invert) const { return invert ? "=" : "<>"; }
protected:
virtual Item_bool_func *create_scalar_predicate(Item *a, Item *b) const;
virtual Item_bool_func *combine(List<Item> list) const;
};
class Gt_creator : public Comp_creator {
public:
Gt_creator() {} /* Remove gcc warning */
virtual ~Gt_creator() {} /* Remove gcc warning */
virtual Item_bool_func *create(Item *a, Item *b) const;
virtual const char *symbol(bool invert) const { return invert ? "<=" : ">"; }
virtual bool eqne_op() const { return 0; }
virtual bool l_op() const { return 0; }
};
class Lt_creator : public Comp_creator {
public:
Lt_creator() {} /* Remove gcc warning */
virtual ~Lt_creator() {} /* Remove gcc warning */
virtual Item_bool_func *create(Item *a, Item *b) const;
virtual const char *symbol(bool invert) const { return invert ? ">=" : "<"; }
virtual bool eqne_op() const { return 0; }
virtual bool l_op() const { return 1; }
};
class Ge_creator : public Comp_creator {
public:
Ge_creator() {} /* Remove gcc warning */
virtual ~Ge_creator() {} /* Remove gcc warning */
virtual Item_bool_func *create(Item *a, Item *b) const;
virtual const char *symbol(bool invert) const { return invert ? "<" : ">="; }
virtual bool eqne_op() const { return 0; }
virtual bool l_op() const { return 0; }
};
class Le_creator : public Comp_creator {
public:
Le_creator() {} /* Remove gcc warning */
virtual ~Le_creator() {} /* Remove gcc warning */
virtual Item_bool_func *create(Item *a, Item *b) const;
virtual const char *symbol(bool invert) const { return invert ? ">" : "<="; }
virtual bool eqne_op() const { return 0; }
virtual bool l_op() const { return 1; }
};
class Item_bool_func2 : public Item_bool_func { /* Bool with 2 string args */
private:
bool convert_constant_arg(THD *thd, Item *field, Item **item,
bool *converted);
protected:
Arg_comparator cmp;
bool abort_on_null;
public:
Item_bool_func2(Item *a, Item *b)
: Item_bool_func(a, b), cmp(tmp_arg, tmp_arg + 1), abort_on_null(false) {}
Item_bool_func2(const POS &pos, Item *a, Item *b)
: Item_bool_func(pos, a, b),
cmp(tmp_arg, tmp_arg + 1),
abort_on_null(false) {}
bool resolve_type(THD *) override;
bool set_cmp_func() {
return cmp.set_cmp_func(this, tmp_arg, tmp_arg + 1, true);
}
/**
When comparing strings, compare at most max_str_length bytes.
@param max_str_length how much to compare
*/
void set_max_str_length(size_t max_str_length) {
return cmp.set_max_str_length(max_str_length);
}
optimize_type select_optimize(const THD *) override { return OPTIMIZE_OP; }
virtual enum Functype rev_functype() const { return UNKNOWN_FUNC; }
bool have_rev_func() const override { return rev_functype() != UNKNOWN_FUNC; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override {
Item_func::print_op(thd, str, query_type);
}
bool is_null() override { return args[0]->is_null() || args[1]->is_null(); }
const CHARSET_INFO *compare_collation() const override {
return cmp.cmp_collation.collation;
}
void apply_is_true() override { abort_on_null = true; }
/// Treat UNKNOWN result like FALSE because callers see no difference
bool ignore_unknown() const { return abort_on_null; }
void cleanup() override {
Item_bool_func::cleanup();
cmp.cleanup();
}
bool cast_incompatible_args(uchar *) override;
friend class Arg_comparator;
};
/**
Item_func_comparison is a class for comparison functions that take two
arguments and return a boolean result.
It is a common class for the regular comparison operators (=, <>, <, <=,
>, >=) as well as the special <=> equality operator.
*/
class Item_func_comparison : public Item_bool_func2 {
public:
Item_func_comparison(Item *a, Item *b) : Item_bool_func2(a, b) {
allowed_arg_cols = 0; // Fetch this value from first argument
}
Item_func_comparison(const POS &pos, Item *a, Item *b)
: Item_bool_func2(pos, a, b) {
allowed_arg_cols = 0; // Fetch this value from first argument
}
Item *truth_transformer(THD *, Bool_test) override;
virtual Item *negated_item();
bool subst_argument_checker(uchar **) override { return true; }
bool is_null() override;
bool has_any_non_equi_join_condition() const override;
};
/**
XOR inherits from Item_bool_func2 because it is not optimized yet.
Later, when XOR is optimized, it needs to inherit from
Item_cond instead. See WL#5800.
*/
class Item_func_xor final : public Item_bool_func2 {
typedef Item_bool_func2 super;
public:
Item_func_xor(Item *i1, Item *i2) : Item_bool_func2(i1, i2) {}
Item_func_xor(const POS &pos, Item *i1, Item *i2)
: Item_bool_func2(pos, i1, i2) {}
enum Functype functype() const override { return XOR_FUNC; }
const char *func_name() const override { return "xor"; }
bool itemize(Parse_context *pc, Item **res) override;
longlong val_int() override;
void apply_is_true() override {}
Item *truth_transformer(THD *, Bool_test) override;
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
bool cast_incompatible_args(uchar *) override { return false; }
};
class Item_func_not : public Item_bool_func {
public:
Item_func_not(Item *a) : Item_bool_func(a) {}
Item_func_not(const POS &pos, Item *a) : Item_bool_func(pos, a) {}
longlong val_int() override;
enum Functype functype() const override { return NOT_FUNC; }
const char *func_name() const override { return "not"; }
Item *truth_transformer(THD *, Bool_test) override;
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
/**
Wrapper class when MATCH function is used in WHERE clause.
The MATCH clause can be used as a function returning a floating point value
in the SELECT list or in the WHERE clause. However, it may also be used as
a boolean function in the WHERE clause, where it has different semantics than
when used together with a comparison operator. With a comparison operator,
the match operation is performed with ranking. To preserve this behavior,
the Item_func_match object is wrapped inside an object of class
Item_func_match_predicate, which effectively transforms the function into
a predicate. The overridden functions implemented in this class generally
forward all evaluation to the underlying object.
*/
class Item_func_match_predicate : public Item_bool_func {
public:
Item_func_match_predicate(Item *a) : Item_bool_func(a) {}
longlong val_int() override { return args[0]->val_int(); }
enum Functype functype() const override { return MATCH_FUNC; }
const char *func_name() const override { return "match"; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override {
args[0]->print(thd, str, query_type);
}
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override {
return args[0]->get_filtering_effect(thd, filter_for_table, read_tables,
fields_to_ignore, rows_in_table);
}
};
class Item_maxmin_subselect;
class JOIN;
/*
trigcond<param>(arg) ::= param? arg : true
The class Item_func_trig_cond is used for guarded predicates
which are employed only for internal purposes.
A guarded predicate is an object consisting of an a regular or
a guarded predicate P and a pointer to a boolean guard variable g.
A guarded predicate P/g is evaluated to true if the value of the
guard g is false, otherwise it is evaluated to the same value that
the predicate P: val(P/g)= g ? val(P):true.
Guarded predicates allow us to include predicates into a conjunction
conditionally. Currently they are utilized for pushed down predicates
in queries with outer join operations.
In the future, probably, it makes sense to extend this class to
the objects consisting of three elements: a predicate P, a pointer
to a variable g and a firing value s with following evaluation
rule: val(P/g,s)= g==s? val(P) : true. It will allow us to build only
one item for the objects of the form P/g1/g2...
Objects of this class are built only for query execution after
the execution plan has been already selected. That's why this
class needs only val_int out of generic methods.
Current uses of Item_func_trig_cond objects:
- To wrap selection conditions when executing outer joins
- To wrap condition that is pushed down into subquery
*/
class Item_func_trig_cond final : public Item_bool_func {
public:
enum enum_trig_type {
/**
This trigger type deactivates join conditions when a row has been
NULL-complemented. For example, in t1 LEFT JOIN t2, the join condition
can be tested on t2's row only if that row is not NULL-complemented.
*/
IS_NOT_NULL_COMPL,
/**
This trigger type deactivates predicated from WHERE condition when no
row satisfying the join condition has been found. For Example, in t1
LEFT JOIN t2, the where condition pushed to t2 can be tested only after
at least one t2 row has been produced, which may be a NULL-complemented
row.
*/
FOUND_MATCH,
/**
In IN->EXISTS subquery transformation, new predicates are added:
WHERE inner_field=outer_field OR inner_field IS NULL,
as well as
HAVING inner_field IS NOT NULL,
are disabled if outer_field is a NULL value
*/
OUTER_FIELD_IS_NOT_NULL
};
private:
/** Pointer to trigger variable */
bool *trig_var;
/// Optional: JOIN of table which is the source of trig_var
const JOIN *m_join;
/// Optional: if join!=NULL: index of table
plan_idx m_idx;
/** Type of trig_var; for printing */
enum_trig_type trig_type;
public:
/**
@param a the item for @<condition@>
@param f pointer to trigger variable
@param join if a table's property is the source of 'f', JOIN
which owns this table; NULL otherwise.
@param idx if join!=NULL: index of this table in the
JOIN_TAB/QEP_TAB array. NO_PLAN_IDX otherwise.
@param trig_type_arg type of 'f'
*/
Item_func_trig_cond(Item *a, bool *f, JOIN *join, plan_idx idx,
enum_trig_type trig_type_arg)
: Item_bool_func(a),
trig_var(f),
m_join(join),
m_idx(idx),
trig_type(trig_type_arg) {}
longlong val_int() override;
enum Functype functype() const override { return TRIG_COND_FUNC; }
/// '@<if@>', to distinguish from the if() SQL function
const char *func_name() const override { return "<if>"; }
/// Get range of inner tables spanned by associated outer join operation
void get_table_range(TABLE_LIST **first_table, TABLE_LIST **last_table) const;
/// Get table_map of inner tables spanned by associated outer join operation
table_map get_inner_tables() const;
bool fix_fields(THD *thd, Item **ref) override {
if (Item_bool_func::fix_fields(thd, ref)) return true;
add_trig_func_tables();
return false;
}
void add_trig_func_tables() {
if (trig_type == IS_NOT_NULL_COMPL || trig_type == FOUND_MATCH) {
DBUG_ASSERT(m_join != nullptr);
// Make this function dependent on the inner tables
used_tables_cache |= get_inner_tables();
} else if (trig_type == OUTER_FIELD_IS_NOT_NULL) {
used_tables_cache |= OUTER_REF_TABLE_BIT;
}
}
void update_used_tables() override {
Item_bool_func::update_used_tables();
add_trig_func_tables();
}
enum enum_trig_type get_trig_type() const { return trig_type; }
bool *get_trig_var() { return trig_var; }
enum_trig_type get_trig_type() { return trig_type; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
plan_idx idx() const { return m_idx; }
};
class Item_func_not_all : public Item_func_not {
/* allow to check presence of values in max/min optimization */
Item_sum_hybrid *test_sum_item;
Item_maxmin_subselect *test_sub_item;
Item_subselect *subselect;
bool abort_on_null;
public:
bool show;
Item_func_not_all(Item *a)
: Item_func_not(a),
test_sum_item(0),
test_sub_item(0),
subselect(0),
abort_on_null(0),
show(0) {}
void apply_is_true() override { abort_on_null = true; }
/// Treat UNKNOWN result like FALSE because callers see no difference
bool ignore_unknown() const { return abort_on_null; }
longlong val_int() override;
enum Functype functype() const override { return NOT_ALL_FUNC; }
const char *func_name() const override { return "<not>"; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
void set_sum_test(Item_sum_hybrid *item) { test_sum_item = item; }
void set_sub_test(Item_maxmin_subselect *item) { test_sub_item = item; }
void set_subselect(Item_subselect *item) { subselect = item; }
table_map not_null_tables() const override {
/*
See handling of not_null_tables_cache in
Item_in_optimizer::fix_fields().
This item is the result of a transformation from an ALL clause
such as
left-expr < ALL(subquery)
into
<not>(left-expr >= ANY(subquery)
An inequality usually rejects NULLs from both operands, so the
not_null_tables() of the inequality is the union of the
null-rejecting tables of both operands. However, since this is a
transformed ALL clause that should return true if the subquery
is empty (even if left-expr is NULL), it is not null rejecting
for left-expr. The not null tables mask for left-expr should be
removed, leaving only the null-rejecting tables of the
subquery. Item_subselect::not_null_tables() always returns 0 (no
null-rejecting tables). Therefore, always return 0.
*/
return 0;
}
bool empty_underlying_subquery();
Item *truth_transformer(THD *, Bool_test) override;
};
class Item_func_nop_all final : public Item_func_not_all {
public:
Item_func_nop_all(Item *a) : Item_func_not_all(a) {}
longlong val_int() override;
const char *func_name() const override { return "<nop>"; }
table_map not_null_tables() const override { return not_null_tables_cache; }
Item *truth_transformer(THD *, Bool_test) override;
};
/**
Implements the comparison operator equals (=)
*/
class Item_func_eq : public Item_func_comparison {
public:
Item_func_eq(Item *a, Item *b) : Item_func_comparison(a, b) {}
Item_func_eq(const POS &pos, Item *a, Item *b)
: Item_func_comparison(pos, a, b) {}
longlong val_int() override;
enum Functype functype() const override { return EQ_FUNC; }
enum Functype rev_functype() const override { return EQ_FUNC; }
cond_result eq_cmp_result() const override { return COND_TRUE; }
const char *func_name() const override { return "="; }
Item *negated_item() override;
bool equality_substitution_analyzer(uchar **) override { return true; }
Item *equality_substitution_transformer(uchar *arg) override;
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
bool has_any_hash_join_condition(const table_map left_tables,
const QEP_TAB &right_table) const override;
/// Read the value from the join condition, and append it to the output vector
/// "join_key_buffer". The function will determine which side of the condition
/// to read the value from by using the bitmap "tables".
///
/// @param thd the thread handler
/// @param tables a bitmap that marks the tables that are involved in the join
/// @param join_condition an isntance containing the join condition together
/// with some pre-calculated values
/// @param[out] join_key_buffer a buffer where the value from the join
/// condition will be appended
///
/// @returns true if an SQL NULL was encountered, false otherwise
bool append_join_key_for_hash_join(THD *thd, table_map tables,
const HashJoinCondition &join_condition,
String *join_key_buffer) const;
/// Wrap the argument in a typecast, if needed.
///
/// When computing a hash of the join value during a hash join, we want to
/// create a hash value that is memcmp-able. This is quite straightforward
/// for most data types, but it can be tricky for some types. For the
/// straightforward cases, this function just returns the argument it was
/// given in. For the complex cases, the function returns the given argument,
/// wrapped in a typecast node. Which typecast node it is wrapped in is
/// determined by the comparison context of this equality condition. The
/// comparison context is given by the member "cmp"; a comparator class that
/// is set up during query resolving.
///
/// @param mem_root the MEM_ROOT where the typecast node is allocated
/// @param argument the argument that we might wrap in a typecast. This is
/// either the left or the right side of the Item_func_eq
///
/// @returns either the argument it was given, or the argument wrapped in a
/// typecast
Item *create_cast_if_needed(MEM_ROOT *mem_root, Item *argument) const;
};
/**
The <=> operator evaluates the same as
a IS NULL || b IS NULL ? a IS NULL == b IS NULL : a = b
a <=> b is equivalent to the standard operation a IS NOT DISTINCT FROM b.
Notice that the result is TRUE or FALSE, and never UNKNOWN.
*/
class Item_func_equal final : public Item_func_comparison {
public:
Item_func_equal(Item *a, Item *b) : Item_func_comparison(a, b) {
null_on_null = false;
}
Item_func_equal(const POS &pos, Item *a, Item *b)
: Item_func_comparison(pos, a, b) {
null_on_null = false;
}
longlong val_int() override;
bool resolve_type(THD *thd) override;
enum Functype functype() const override { return EQUAL_FUNC; }
enum Functype rev_functype() const override { return EQUAL_FUNC; }
cond_result eq_cmp_result() const override { return COND_TRUE; }
const char *func_name() const override { return "<=>"; }
Item *truth_transformer(THD *, Bool_test) override { return nullptr; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
/**
Implements the comparison operator greater than or equals (>=)
*/
class Item_func_ge final : public Item_func_comparison {
public:
Item_func_ge(Item *a, Item *b) : Item_func_comparison(a, b) {}
longlong val_int() override;
enum Functype functype() const override { return GE_FUNC; }
enum Functype rev_functype() const override { return LE_FUNC; }
cond_result eq_cmp_result() const override { return COND_TRUE; }
const char *func_name() const override { return ">="; }
Item *negated_item() override;
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
/**
Implements the comparison operator greater than (>)
*/
class Item_func_gt final : public Item_func_comparison {
public:
Item_func_gt(Item *a, Item *b) : Item_func_comparison(a, b) {}
longlong val_int() override;
enum Functype functype() const override { return GT_FUNC; }
enum Functype rev_functype() const override { return LT_FUNC; }
cond_result eq_cmp_result() const override { return COND_FALSE; }
const char *func_name() const override { return ">"; }
Item *negated_item() override;
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
/**
Implements the comparison operator less than or equals (<=)
*/
class Item_func_le final : public Item_func_comparison {
public:
Item_func_le(Item *a, Item *b) : Item_func_comparison(a, b) {}
longlong val_int() override;
enum Functype functype() const override { return LE_FUNC; }
enum Functype rev_functype() const override { return GE_FUNC; }
cond_result eq_cmp_result() const override { return COND_TRUE; }
const char *func_name() const override { return "<="; }
Item *negated_item() override;
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
/**
Implements the comparison operator less than (<)
*/
class Item_func_lt final : public Item_func_comparison {
public:
Item_func_lt(Item *a, Item *b) : Item_func_comparison(a, b) {}
longlong val_int() override;
enum Functype functype() const override { return LT_FUNC; }
enum Functype rev_functype() const override { return GT_FUNC; }
cond_result eq_cmp_result() const override { return COND_FALSE; }
const char *func_name() const override { return "<"; }
Item *negated_item() override;
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
/**
Implements the comparison operator not equals (<>)
*/
class Item_func_ne final : public Item_func_comparison {
public:
Item_func_ne(Item *a, Item *b) : Item_func_comparison(a, b) {}
longlong val_int() override;
enum Functype functype() const override { return NE_FUNC; }
cond_result eq_cmp_result() const override { return COND_FALSE; }
optimize_type select_optimize(const THD *) override { return OPTIMIZE_KEY; }
const char *func_name() const override { return "<>"; }
Item *negated_item() override;
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
/*
The class Item_func_opt_neg is defined to factor out the functionality
common for the classes Item_func_between and Item_func_in. The objects
of these classes can express predicates or their negations.
The alternative approach would be to create pairs Item_func_between,
Item_func_notbetween and Item_func_in, Item_func_notin.
*/
class Item_func_opt_neg : public Item_int_func {
public:
bool negated; /* <=> the item represents NOT <func> */
bool pred_level; /* <=> [NOT] <func> is used on a predicate level */
public:
Item_func_opt_neg(const POS &pos, Item *a, Item *b, Item *c, bool is_negation)
: Item_int_func(pos, a, b, c), negated(0), pred_level(0) {
if (is_negation) negate();
}
Item_func_opt_neg(const POS &pos, PT_item_list *list, bool is_negation)
: Item_int_func(pos, list), negated(0), pred_level(0) {
if (is_negation) negate();
}
public:
inline void negate() { negated = !negated; }
inline void apply_is_true() override { pred_level = 1; }
bool ignore_unknown() const { return pred_level; }
Item *truth_transformer(THD *, Bool_test test) override {
if (test != BOOL_NEGATED) return nullptr;
negated = !negated;
return this;
}
bool eq(const Item *item, bool binary_cmp) const override;
bool subst_argument_checker(uchar **) override { return true; }
};
class Item_func_between final : public Item_func_opt_neg {
DTCollation cmp_collation;
public:
Item_result cmp_type;
String value0, value1, value2;
/* true <=> arguments will be compared as dates. */
bool compare_as_dates_with_strings;
bool compare_as_temporal_dates;
bool compare_as_temporal_times;
/* Comparators used for DATE/DATETIME comparison. */
Arg_comparator ge_cmp, le_cmp;
Item_func_between(const POS &pos, Item *a, Item *b, Item *c, bool is_negation)
: Item_func_opt_neg(pos, a, b, c, is_negation),
compare_as_dates_with_strings(false),
compare_as_temporal_dates(false),
compare_as_temporal_times(false) {}
longlong val_int() override;
optimize_type select_optimize(const THD *) override { return OPTIMIZE_KEY; }
enum Functype functype() const override { return BETWEEN; }
const char *func_name() const override { return "between"; }
bool fix_fields(THD *, Item **) override;
void fix_after_pullout(SELECT_LEX *parent_select,
SELECT_LEX *removed_select) override;
bool resolve_type(THD *) override;
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
bool is_bool_func() const override { return true; }
const CHARSET_INFO *compare_collation() const override {
return cmp_collation.collation;
}
uint decimal_precision() const override { return 1; }
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
class Item_func_strcmp final : public Item_bool_func2 {
public:
Item_func_strcmp(const POS &pos, Item *a, Item *b)
: Item_bool_func2(pos, a, b) {}
longlong val_int() override;
optimize_type select_optimize(const THD *) override { return OPTIMIZE_NONE; }
const char *func_name() const override { return "strcmp"; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override {
Item_func::print(thd, str, query_type);
}
bool resolve_type(THD *thd) override {
if (Item_bool_func2::resolve_type(thd)) return true;
fix_char_length(2); // returns "1" or "0" or "-1"
return false;
}
};
struct interval_range {
Item_result type;
double dbl;
my_decimal dec;
};
class Item_func_interval final : public Item_int_func {
typedef Item_int_func super;
Item_row *row;
bool use_decimal_comparison;
interval_range *intervals;
public:
Item_func_interval(const POS &pos, MEM_ROOT *mem_root, Item *expr1,
Item *expr2, class PT_item_list *opt_expr_list = NULL)
: super(pos, alloc_row(pos, mem_root, expr1, expr2, opt_expr_list)),
row(down_cast<Item_row *>(args[0])),
intervals(0) {
allowed_arg_cols = 0; // Fetch this value from first argument
}
bool itemize(Parse_context *pc, Item **res) override;
longlong val_int() override;
bool resolve_type(THD *) override;
const char *func_name() const override { return "interval"; }
uint decimal_precision() const override { return 2; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
private:
// Runs in CTOR init list, cannot access *this as Item_func_interval
static Item_row *alloc_row(const POS &pos, MEM_ROOT *mem_root, Item *expr1,
Item *expr2, class PT_item_list *opt_expr_list);
};
class Item_func_coalesce : public Item_func_numhybrid {
protected:
Item_func_coalesce(const POS &pos, Item *a, Item *b)
: Item_func_numhybrid(pos, a, b) {
null_on_null = false;
}
Item_func_coalesce(const POS &pos, Item *a) : Item_func_numhybrid(pos, a) {
null_on_null = false;
}
public:
Item_func_coalesce(const POS &pos, PT_item_list *list)
: Item_func_numhybrid(pos, list) {
null_on_null = false;
}
double real_op() override;
longlong int_op() override;
String *str_op(String *) override;
/**
Get the result of COALESCE as a JSON value.
@param[in,out] wr the result value holder
*/
bool val_json(Json_wrapper *wr) override;
bool date_op(MYSQL_TIME *ltime, my_time_flags_t fuzzydate) override;
bool time_op(MYSQL_TIME *ltime) override;
my_decimal *decimal_op(my_decimal *) override;
bool resolve_type(THD *) override;
void set_numeric_type() override {}
enum Item_result result_type() const override { return hybrid_type; }
const char *func_name() const override { return "coalesce"; }
enum Functype functype() const override { return COALESCE_FUNC; }
};
class Item_func_ifnull final : public Item_func_coalesce {
protected:
bool field_type_defined;
public:
Item_func_ifnull(const POS &pos, Item *a, Item *b)
: Item_func_coalesce(pos, a, b) {}
double real_op() override;
longlong int_op() override;
String *str_op(String *str) override;
bool date_op(MYSQL_TIME *ltime, my_time_flags_t fuzzydate) override;
bool time_op(MYSQL_TIME *ltime) override;
my_decimal *decimal_op(my_decimal *) override;
bool val_json(Json_wrapper *result) override;
const char *func_name() const override { return "ifnull"; }
Field *tmp_table_field(TABLE *table) override;
uint decimal_precision() const override;
};
/**
ANY_VALUE(expr) is like expr except that it is not checked by
aggregate_check logic. It serves as a solution for users who want to
bypass this logic.
*/
class Item_func_any_value final : public Item_func_coalesce {
public:
Item_func_any_value(const POS &pos, Item *a) : Item_func_coalesce(pos, a) {}
const char *func_name() const override { return "any_value"; }
bool aggregate_check_group(uchar *arg) override;
bool aggregate_check_distinct(uchar *arg) override;
};
class Item_func_if final : public Item_func {
enum Item_result cached_result_type;
public:
Item_func_if(Item *a, Item *b, Item *c)
: Item_func(a, b, c), cached_result_type(INT_RESULT) {
null_on_null = false;
}
Item_func_if(const POS &pos, Item *a, Item *b, Item *c)
: Item_func(pos, a, b, c), cached_result_type(INT_RESULT) {
null_on_null = false;
}
double val_real() override;
longlong val_int() override;
String *val_str(String *str) override;
my_decimal *val_decimal(my_decimal *) override;
bool val_json(Json_wrapper *wr) override;
bool get_date(MYSQL_TIME *ltime, my_time_flags_t fuzzydate) override;
bool get_time(MYSQL_TIME *ltime) override;
enum Item_result result_type() const override { return cached_result_type; }
bool fix_fields(THD *, Item **) override;
bool resolve_type(THD *) override;
void fix_after_pullout(SELECT_LEX *parent_select,
SELECT_LEX *removed_select) override;
uint decimal_precision() const override;
const char *func_name() const override { return "if"; }
enum Functype functype() const override { return IF_FUNC; }
};
class Item_func_nullif final : public Item_bool_func2 {
enum Item_result cached_result_type;
public:
Item_func_nullif(const POS &pos, Item *a, Item *b)
: Item_bool_func2(pos, a, b), cached_result_type(INT_RESULT) {
null_on_null = false;
}
double val_real() override;
longlong val_int() override;
String *val_str(String *str) override;
my_decimal *val_decimal(my_decimal *) override;
bool val_json(Json_wrapper *wr) override;
Item_result result_type() const override { return cached_result_type; }
bool resolve_type(THD *thd) override;
uint decimal_precision() const override {
return args[0]->decimal_precision();
}
const char *func_name() const override { return "nullif"; }
enum Functype functype() const override { return NULLIF_FUNC; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override {
Item_func::print(thd, str, query_type);
}
bool is_null() override;
/**
This is a workaround for the broken inheritance hierarchy: this should
inherit from Item_func instead of Item_bool_func2
*/
bool is_bool_func() const override { return false; }
bool cast_incompatible_args(uchar *) override { return false; }
};
/* Functions to handle the optimized IN */
/* A vector of values of some type */
class in_vector {
private:
const uint count; ///< Original size of the vector
public:
uint used_count; ///< The actual size of the vector (NULL may be ignored)
/**
See Item_func_in::resolve_type() for why we need both
count and used_count.
*/
explicit in_vector(uint elements) : count(elements), used_count(elements) {}
virtual ~in_vector() {}
/**
Calls item->val_int() or item->val_str() etc.
and then does binary_search if the value is non-null.
@param item to evaluate, and lookup in the IN-list.
@return true if evaluated value of the item was found.
*/
virtual bool find_item(Item *item) = 0;
/**
Create an instance of Item_{type} (e.g. Item_decimal) constant object
which type allows it to hold an element of this vector without any
conversions.
The purpose of this function is to be able to get elements of this
vector in form of Item_xxx constants without creating Item_xxx object
for every array element you get (i.e. this implements "FlyWeight" pattern)
@param mem_root Where to allocate the Item.
*/
virtual Item_basic_constant *create_item(MEM_ROOT *mem_root) const = 0;
/**
Store the value at position #pos into provided item object
@param pos Index of value to store
@param item Constant item to store value into. The item must be of the same
type that create_item() returns.
*/
virtual void value_to_item(uint pos, Item_basic_constant *item) const = 0;
/** Compare values number pos1 and pos2 for equality */
virtual bool compare_elems(uint pos1, uint pos2) const = 0;
virtual bool is_row_result() const { return false; }
/**
Fill the vector by evaluating the items passed as arguments.
Note that null values are skipped so the vector may end up containing
fewer elements than the number of items.
The vector is sorted so that it can be used for binary search.
@param items Items to evaluate
@param item_count Number of items
@return true if any null values was found, false otherwise.
*/
bool fill(Item **items, uint item_count);
private:
virtual void set(uint pos, Item *item) = 0;
/**
Resize and then sort the IN-list array, so we can do efficient lookup with
binary_search.
*/
virtual void resize_and_sort() = 0;
};
class in_string final : public in_vector {
char buff[STRING_BUFFER_USUAL_SIZE];
String tmp;
Mem_root_array<String> base_objects;
// String objects are not sortable, sort pointers instead.
Mem_root_array<String *> base_pointers;
const CHARSET_INFO *collation;
public:
in_string(MEM_ROOT *mem_root, uint elements, const CHARSET_INFO *cs);
Item_basic_constant *create_item(MEM_ROOT *mem_root) const override {
return new (mem_root) Item_string(collation);
}
void value_to_item(uint pos, Item_basic_constant *item) const override {
item->set_str_value(base_pointers[pos]);
}
bool find_item(Item *item) override;
bool compare_elems(uint pos1, uint pos2) const override;
private:
void set(uint pos, Item *item) override;
void resize_and_sort() override;
};
class in_longlong : public in_vector {
public:
struct packed_longlong {
longlong val;
bool unsigned_flag;
};
protected:
Mem_root_array<packed_longlong> base;
public:
in_longlong(MEM_ROOT *mem_root, uint elements)
: in_vector(elements), base(mem_root, elements) {}
Item_basic_constant *create_item(MEM_ROOT *mem_root) const override {
/*
We've created a signed INT, this may not be correct in the
general case (see BUG#19342).
*/
return new (mem_root) Item_int(0LL);
}
void value_to_item(uint pos, Item_basic_constant *item) const override {
down_cast<Item_int *>(item)->value = base[pos].val;
item->unsigned_flag = base[pos].unsigned_flag;
}
bool find_item(Item *item) override;
bool compare_elems(uint pos1, uint pos2) const override;
private:
void set(uint pos, Item *item) override { val_item(item, &base[pos]); }
void resize_and_sort() override;
virtual void val_item(Item *item, packed_longlong *result);
};
class in_datetime_as_longlong final : public in_longlong {
public:
in_datetime_as_longlong(MEM_ROOT *mem_root, uint elements)
: in_longlong(mem_root, elements) {}
Item_basic_constant *create_item(MEM_ROOT *mem_root) const override {
return new (mem_root) Item_temporal(MYSQL_TYPE_DATETIME, 0LL);
}
private:
void val_item(Item *item, packed_longlong *result) override;
};
class in_time_as_longlong final : public in_longlong {
public:
in_time_as_longlong(MEM_ROOT *mem_root, uint elements)
: in_longlong(mem_root, elements) {}
Item_basic_constant *create_item(MEM_ROOT *mem_root) const override {
return new (mem_root) Item_temporal(MYSQL_TYPE_TIME, 0LL);
}
private:
void val_item(Item *item, packed_longlong *result) override;
};
/*
Class to represent a vector of constant DATE/DATETIME values.
Values are obtained with help of the get_datetime_value() function.
If the left item is a constant one then its value is cached in the
lval_cache variable.
*/
class in_datetime final : public in_longlong {
/* An item used to issue warnings. */
Item *warn_item;
/* Cache for the left item. */
Item *lval_cache;
public:
in_datetime(MEM_ROOT *mem_root, Item *warn_item_arg, uint elements)
: in_longlong(mem_root, elements),
warn_item(warn_item_arg),
lval_cache(nullptr) {}
Item_basic_constant *create_item(MEM_ROOT *mem_root) const override {
return new (mem_root) Item_temporal(MYSQL_TYPE_DATETIME, 0LL);
}
private:
void set(uint pos, Item *item) override;
void val_item(Item *item, packed_longlong *result) override;
};
class in_double final : public in_vector {
Mem_root_array<double> base;
public:
in_double(MEM_ROOT *mem_root, uint elements)
: in_vector(elements), base(mem_root, elements) {}
Item_basic_constant *create_item(MEM_ROOT *mem_root) const override {
return new (mem_root) Item_float(0.0, 0);
}
void value_to_item(uint pos, Item_basic_constant *item) const override {
down_cast<Item_float *>(item)->value = base[pos];
}
bool find_item(Item *item) override;
bool compare_elems(uint pos1, uint pos2) const override;
private:
void set(uint pos, Item *item) override;
void resize_and_sort() override;
};
class in_decimal final : public in_vector {
Mem_root_array<my_decimal> base;
public:
in_decimal(MEM_ROOT *mem_root, uint elements)
: in_vector(elements), base(mem_root, elements) {}
Item_basic_constant *create_item(MEM_ROOT *mem_root) const override {
return new (mem_root) Item_decimal(0, false);
}
void value_to_item(uint pos, Item_basic_constant *item) const override {
down_cast<Item_decimal *>(item)->set_decimal_value(&base[pos]);
}
bool find_item(Item *item) override;
bool compare_elems(uint pos1, uint pos2) const override;
private:
void set(uint pos, Item *item) override;
void resize_and_sort() override;
};
/*
** Classes for easy comparing of non const items
*/
class cmp_item {
public:
cmp_item() {}
virtual ~cmp_item() {}
virtual void store_value(Item *item) = 0;
/**
@returns result (true, false or UNKNOWN) of
"stored argument's value <> item's value"
*/
virtual int cmp(Item *item) = 0;
// for optimized IN with row
virtual int compare(const cmp_item *item) const = 0;
/**
Find the appropriate comparator for the given type.
@param result_type Used to find the appropriate comparator.
@param item Item object used to distinguish temporal types.
@param cs Charset
@return
New cmp_item_xxx object.
*/
static cmp_item *get_comparator(Item_result result_type, const Item *item,
const CHARSET_INFO *cs);
virtual cmp_item *make_same() = 0;
virtual void store_value_by_template(cmp_item *, Item *item) {
store_value(item);
}
};
/// cmp_item which stores a scalar (i.e. non-ROW).
class cmp_item_scalar : public cmp_item {
protected:
bool m_null_value; ///< If stored value is NULL
void set_null_value(bool nv) { m_null_value = nv; }
};
class cmp_item_string final : public cmp_item_scalar {
private:
String *value_res;
char value_buff[STRING_BUFFER_USUAL_SIZE];
String value;
const CHARSET_INFO *cmp_charset;
public:
cmp_item_string(const CHARSET_INFO *cs)
: value(value_buff, sizeof(value_buff), cs), cmp_charset(cs) {}
virtual int compare(const cmp_item *ci) const {
const cmp_item_string *l_cmp = down_cast<const cmp_item_string *>(ci);
return sortcmp(value_res, l_cmp->value_res, cmp_charset);
}
virtual void store_value(Item *item) {
String *res = item->val_str(&value);
if (res && (res != &value || !res->is_alloced())) {
// 'res' may point in item's transient internal data, so make a copy
value.copy(*res);
}
value_res = &value;
set_null_value(item->null_value);
}
virtual int cmp(Item *arg) {
char buff[STRING_BUFFER_USUAL_SIZE];
String tmp(buff, sizeof(buff), cmp_charset);
String *res = arg->val_str(&tmp);
if (m_null_value || arg->null_value) return UNKNOWN;
if (value_res && res)
return sortcmp(value_res, res, cmp_charset) != 0;
else if (!value_res && !res)
return false;
else
return true;
}
virtual cmp_item *make_same();
};
class cmp_item_json final : public cmp_item_scalar {
private:
/// Cached JSON value to look up
Json_wrapper m_value;
/// Cache for the value above
Json_scalar_holder m_holder;
/// String buffer
String m_str_value;
/// Scalar holder for the RHS value
Json_scalar_holder m_itm_holder;
public:
cmp_item_json() {}
virtual int compare(const cmp_item *ci) const;
virtual void store_value(Item *item);
virtual int cmp(Item *arg);
virtual cmp_item *make_same();
};
class cmp_item_int final : public cmp_item_scalar {
longlong value;
public:
cmp_item_int() {} /* Remove gcc warning */
void store_value(Item *item) override {
value = item->val_int();
set_null_value(item->null_value);
}
int cmp(Item *arg) override {
const bool rc = value != arg->val_int();
return (m_null_value || arg->null_value) ? UNKNOWN : rc;
}
int compare(const cmp_item *ci) const override {
const cmp_item_int *l_cmp = down_cast<const cmp_item_int *>(ci);
return (value < l_cmp->value) ? -1 : ((value == l_cmp->value) ? 0 : 1);
}
cmp_item *make_same() override;
};
/*
Compare items of temporal type.
Values are obtained with: get_datetime_value() (DATE/DATETIME/TIMESTAMP) and
get_time_value() (TIME).
If the left item is a constant one then its value is cached in the
lval_cache variable.
*/
class cmp_item_datetime : public cmp_item_scalar {
longlong value;
public:
/* Item used for issuing warnings. */
const Item *warn_item;
/* Cache for the left item. */
Item *lval_cache;
/// Distinguish between DATE/DATETIME/TIMESTAMP and TIME
bool has_date;
cmp_item_datetime(const Item *warn_item_arg);
void store_value(Item *item) override;
int cmp(Item *arg) override;
int compare(const cmp_item *ci) const override;
cmp_item *make_same() override;
};
class cmp_item_real : public cmp_item_scalar {
double value;
public:
cmp_item_real() {} /* Remove gcc warning */
void store_value(Item *item) override {
value = item->val_real();
set_null_value(item->null_value);
}
int cmp(Item *arg) override {
const bool rc = value != arg->val_real();
return (m_null_value || arg->null_value) ? UNKNOWN : rc;
}
int compare(const cmp_item *ci) const override {
const cmp_item_real *l_cmp = down_cast<const cmp_item_real *>(ci);
return (value < l_cmp->value) ? -1 : ((value == l_cmp->value) ? 0 : 1);
}
cmp_item *make_same() override;
};
class cmp_item_decimal : public cmp_item_scalar {
my_decimal value;
public:
cmp_item_decimal() {} /* Remove gcc warning */
void store_value(Item *item);
int cmp(Item *arg);
int compare(const cmp_item *c) const;
cmp_item *make_same();
};
/**
CASE ... WHEN ... THEN ... END function implementation.
When there is no expression between CASE and the first WHEN
(the CASE expression) then this function simple checks all WHEN expressions
one after another. When some WHEN expression evaluated to TRUE then the
value of the corresponding THEN expression is returned.
When the CASE expression is specified then it is compared to each WHEN
expression individually. When an equal WHEN expression is found
corresponding THEN expression is returned.
In order to do correct comparisons several comparators are used. One for
each result type. Different result types that are used in particular
CASE ... END expression are collected in the resolve_type() member
function and only comparators for there result types are used.
*/
class Item_func_case final : public Item_func {
typedef Item_func super;
int first_expr_num, else_expr_num;
enum Item_result cached_result_type, left_result_type;
String tmp_value;
uint ncases;
Item_result cmp_type;
DTCollation cmp_collation;
cmp_item *cmp_items[5]; /* For all result types */
cmp_item *case_item;
public:
Item_func_case(const POS &pos, List<Item> &list, Item *first_expr_arg,
Item *else_expr_arg)
: super(pos),
first_expr_num(-1),
else_expr_num(-1),
cached_result_type(INT_RESULT),
left_result_type(INT_RESULT),
case_item(0) {
null_on_null = false;
ncases = list.elements;
if (first_expr_arg) {
first_expr_num = list.elements;
list.push_back(first_expr_arg);
}
if (else_expr_arg) {
else_expr_num = list.elements;
list.push_back(else_expr_arg);
}
set_arguments(list, true);
memset(&cmp_items, 0, sizeof(cmp_items));
}
int get_first_expr_num() const { return first_expr_num; }
int get_else_expr_num() const { return else_expr_num; }
double val_real() override;
longlong val_int() override;
String *val_str(String *) override;
my_decimal *val_decimal(my_decimal *) override;
bool val_json(Json_wrapper *wr) override;
bool get_date(MYSQL_TIME *ltime, my_time_flags_t fuzzydate) override;
bool get_time(MYSQL_TIME *ltime) override;
bool fix_fields(THD *thd, Item **ref) override;
bool resolve_type(THD *) override;
uint decimal_precision() const override;
enum Item_result result_type() const override { return cached_result_type; }
const char *func_name() const override { return "case"; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
Item *find_item(String *str);
const CHARSET_INFO *compare_collation() const override {
return cmp_collation.collation;
}
void cleanup() override;
enum Functype functype() const override { return CASE_FUNC; }
};
/**
in_expr [NOT] IN (in_value_list).
The current implementation distinguishes 2 cases:
1) all items in in_value_list are constants and have the same
result type. This case is handled by in_vector class.
2) otherwise Item_func_in employs several cmp_item objects to perform
comparisons of in_expr and an item from in_value_list. One cmp_item
object for each result type. Different result types are collected in the
resolve_type() member function by means of collect_cmp_types() function.
*/
class Item_func_in final : public Item_func_opt_neg {
public:
/// An array of values, created when the bisection lookup method is used
in_vector *array;
/**
If there is some NULL among @<in value list@>, during a val_int() call; for
example
IN ( (1,(3,'col')), ... ), where 'col' is a column which evaluates to
NULL.
*/
bool have_null;
/**
Set to true by resolve_type() if the IN list contains a
dependent subquery, in which case condition filtering will not be
calculated for this item.
*/
bool dep_subq_in_list;
Item_result left_result_type;
cmp_item *cmp_items[6]; /* One cmp_item for each result type */
DTCollation cmp_collation;
Item_func_in(const POS &pos, PT_item_list *list, bool is_negation)
: Item_func_opt_neg(pos, list, is_negation),
array(NULL),
have_null(false),
dep_subq_in_list(false) {
memset(&cmp_items, 0, sizeof(cmp_items));
allowed_arg_cols = 0; // Fetch this value from first argument
}
longlong val_int() override;
bool fix_fields(THD *, Item **) override;
void fix_after_pullout(SELECT_LEX *parent_select,
SELECT_LEX *removed_select) override;
bool resolve_type(THD *) override;
uint decimal_precision() const override { return 1; }
/**
Cleanup data and comparator arrays.
@note Used during regular cleanup and to free arrays after GC substitution.
@see substitute_gc().
*/
void cleanup_arrays() {
uint i;
destroy(array);
array = 0;
for (i = 0; i <= (uint)DECIMAL_RESULT + 1; i++) {
destroy(cmp_items[i]);
cmp_items[i] = 0;
}
}
void cleanup() override {
DBUG_TRACE;
Item_int_func::cleanup();
cleanup_arrays();
return;
}
optimize_type select_optimize(const THD *) override { return OPTIMIZE_KEY; }
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
enum Functype functype() const override { return IN_FUNC; }
const char *func_name() const override { return " IN "; }
bool is_bool_func() const override { return true; }
const CHARSET_INFO *compare_collation() const override {
return cmp_collation.collation;
}
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
private:
/**
Usable if @<in value list@> is made only of constants. Returns true if one
of these constants contains a NULL. Example:
IN ( (-5, (12,NULL)), ... ).
*/
bool list_contains_null();
/**
Utility function to help calculate the total filtering effect of
IN predicates. This function calculates the filtering effect from
a single field (or field reference) on the left hand side of the
expression.
@param fieldref Field (or field reference) on left hand side of
IN, i.e., this function should be called for
each fi in "(f1,...,fn) IN (values)"
@param filter_for_table The table we are calculating filter effect for
@param fields_to_ignore Fields in 'filter_for_table' that should not
be part of the filter calculation. The filtering
effect of these fields are already part of the
calculation somehow (e.g. because there is a
predicate "col = <const>", and the optimizer
has decided to do ref access on 'col').
@param rows_in_table The number of rows in table 'filter_for_table'
@return the filtering effect (between 0 and 1) 'the_field'
participates with in this IN predicate.
*/
float get_single_col_filtering_effect(Item_ident *fieldref,
table_map filter_for_table,
const MY_BITMAP *fields_to_ignore,
double rows_in_table);
};
class cmp_item_row : public cmp_item {
cmp_item **comparators;
uint n;
public:
cmp_item_row() : comparators(nullptr), n(0) {}
cmp_item_row(THD *thd, Item *item) : comparators(nullptr), n(item->cols()) {
alloc_comparators(thd, item);
}
~cmp_item_row();
cmp_item_row(cmp_item_row &&other)
: comparators(other.comparators), n(other.n) {
other.comparators = nullptr;
other.n = 0;
}
void store_value(Item *item);
int cmp(Item *arg);
int compare(const cmp_item *arg) const;
cmp_item *make_same();
void store_value_by_template(cmp_item *tmpl, Item *);
void set_comparator(uint col, cmp_item *comparator) {
comparators[col] = comparator;
}
private:
bool alloc_comparators(THD *thd, Item *item);
};
class in_row final : public in_vector {
cmp_item_row *tmp;
Mem_root_array<cmp_item_row> base_objects;
// Sort pointers, rather than objects.
Mem_root_array<cmp_item_row *> base_pointers;
public:
in_row(MEM_ROOT *mem_root, uint elements, cmp_item_row *cmp);
bool is_row_result() const override { return true; }
bool find_item(Item *item) override;
bool compare_elems(uint pos1, uint pos2) const override;
void set_comparator(uint col, cmp_item *comparator) {
tmp->set_comparator(col, comparator);
}
Item_basic_constant *create_item(MEM_ROOT *) const override {
DBUG_ASSERT(false);
return nullptr;
}
void value_to_item(uint, Item_basic_constant *) const override {
DBUG_ASSERT(false);
}
private:
void set(uint pos, Item *item) override;
void resize_and_sort() override;
};
/* Functions used by where clause */
class Item_func_isnull : public Item_bool_func {
typedef Item_bool_func super;
protected:
longlong cached_value;
public:
Item_func_isnull(Item *a) : super(a) { null_on_null = false; }
Item_func_isnull(const POS &pos, Item *a) : super(pos, a) {
null_on_null = false;
}
longlong val_int() override;
enum Functype functype() const override { return ISNULL_FUNC; }
bool resolve_type(THD *thd) override;
const char *func_name() const override { return "isnull"; }
/* Optimize case of not_null_column IS NULL */
void update_used_tables() override;
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
optimize_type select_optimize(const THD *) override { return OPTIMIZE_NULL; }
Item *truth_transformer(THD *, Bool_test test) override;
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
const CHARSET_INFO *compare_collation() const override {
return args[0]->collation.collation;
}
bool fix_fields(THD *thd, Item **ref) override;
};
/* Functions used by HAVING for rewriting IN subquery */
/*
This is like IS NOT NULL but it also remembers if it ever has
encountered a NULL; it remembers this in the "was_null" property of the
"owner" item.
*/
class Item_is_not_null_test final : public Item_func_isnull {
Item_in_subselect *owner;
public:
Item_is_not_null_test(Item_in_subselect *ow, Item *a)
: Item_func_isnull(a), owner(ow) {}
enum Functype functype() const override { return ISNOTNULLTEST_FUNC; }
longlong val_int() override;
const char *func_name() const override { return "<is_not_null_test>"; }
void update_used_tables() override;
/**
We add RAND_TABLE_BIT to prevent moving this item from HAVING to WHERE.
@retval Always RAND_TABLE_BIT
*/
table_map get_initial_pseudo_tables() const override {
return RAND_TABLE_BIT;
}
void print(const THD *thd, String *str,
enum_query_type query_type) const override {
Item_bool_func::print(thd, str, query_type);
}
};
class Item_func_isnotnull final : public Item_bool_func {
public:
Item_func_isnotnull(Item *a) : Item_bool_func(a) { null_on_null = false; }
Item_func_isnotnull(const POS &pos, Item *a) : Item_bool_func(pos, a) {
null_on_null = false;
}
longlong val_int() override;
enum Functype functype() const override { return ISNOTNULL_FUNC; }
bool resolve_type(THD *) override {
max_length = 1;
maybe_null = false;
return false;
}
const char *func_name() const override { return "isnotnull"; }
optimize_type select_optimize(const THD *) override { return OPTIMIZE_NULL; }
Item *truth_transformer(THD *, Bool_test test) override;
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
const CHARSET_INFO *compare_collation() const override {
return args[0]->collation.collation;
}
void apply_is_true() override {
null_on_null = true;
} // Same logic as for Item_func_truth's function
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
class Item_func_like final : public Item_bool_func2 {
typedef Item_bool_func2 super;
Item *escape_item;
bool escape_used_in_parsing;
bool escape_evaluated; ///< Tells if the escape clause has been evaluated.
bool eval_escape_clause(THD *thd);
public:
int escape;
Item_func_like(Item *a, Item *b, Item *escape_arg, bool escape_used)
: Item_bool_func2(a, b),
escape_item(escape_arg),
escape_used_in_parsing(escape_used),
escape_evaluated(false) {}
Item_func_like(const POS &pos, Item *a, Item *b, Item *opt_escape_arg)
: super(pos, a, b),
escape_item(opt_escape_arg),
escape_used_in_parsing(opt_escape_arg != NULL),
escape_evaluated(false) {}
bool itemize(Parse_context *pc, Item **res) override;
longlong val_int() override;
enum Functype functype() const override { return LIKE_FUNC; }
optimize_type select_optimize(const THD *thd) override;
cond_result eq_cmp_result() const override { return COND_TRUE; }
const char *func_name() const override { return "like"; }
bool fix_fields(THD *thd, Item **ref) override;
bool resolve_type(THD *) override;
void cleanup() override;
bool cast_incompatible_args(uchar *) override { return false; }
/**
@retval true non default escape char specified
using "expr LIKE pat ESCAPE 'escape_char'" syntax
*/
bool escape_was_used_in_parsing() const { return escape_used_in_parsing; }
/**
Has the escape clause been evaluated? It only needs to be evaluated
once per execution, since we require it to be constant during execution.
The escape member has a valid value if and only if this function returns
true.
*/
bool escape_is_evaluated() const { return escape_evaluated; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
void update_used_tables() override;
private:
/**
The method updates covering keys depending on the
length of wild string prefix.
@param thd Pointer to THD object.
@retval true if error happens during wild string prefix claculation,
false otherwise.
*/
bool check_covering_prefix_keys(THD *thd);
};
class Item_cond : public Item_bool_func {
typedef Item_bool_func super;
protected:
List<Item> list;
bool abort_on_null;
public:
/* Item_cond() is only used to create top level items */
Item_cond() : Item_bool_func(), abort_on_null(1) {}
Item_cond(Item *i1, Item *i2) : Item_bool_func(), abort_on_null(0) {
list.push_back(i1);
list.push_back(i2);
}
Item_cond(const POS &pos, Item *i1, Item *i2)
: Item_bool_func(pos), abort_on_null(0) {
list.push_back(i1);
list.push_back(i2);
}
Item_cond(THD *thd, Item_cond *item);
Item_cond(List<Item> &nlist)
: Item_bool_func(), list(nlist), abort_on_null(0) {}
bool add(Item *item) {
DBUG_ASSERT(item);
return list.push_back(item);
}
bool add_at_head(Item *item) {
DBUG_ASSERT(item);
return list.push_front(item);
}
void add_at_head(List<Item> *nlist) {
DBUG_ASSERT(nlist->elements);
list.prepend(nlist);
}
bool itemize(Parse_context *pc, Item **res) override;
bool fix_fields(THD *, Item **ref) override;
void fix_after_pullout(SELECT_LEX *parent_select,
SELECT_LEX *removed_select) override;
Type type() const override { return COND_ITEM; }
List<Item> *argument_list() { return &list; }
bool eq(const Item *item, bool binary_cmp) const override;
table_map used_tables() const override { return used_tables_cache; }
void update_used_tables() override;
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
void split_sum_func(THD *thd, Ref_item_array ref_item_array,
List<Item> &fields) override;
void apply_is_true() override { abort_on_null = true; }
void copy_andor_arguments(THD *thd, Item_cond *item);
bool walk(Item_processor processor, enum_walk walk, uchar *arg) override;
Item *transform(Item_transformer transformer, uchar *arg) override;
void traverse_cond(Cond_traverser, void *arg, traverse_order order) override;
bool truth_transform_arguments(THD *thd, Bool_test test);
bool subst_argument_checker(uchar **) override { return true; }
Item *compile(Item_analyzer analyzer, uchar **arg_p,
Item_transformer transformer, uchar *arg_t) override;
bool remove_const_conds(THD *thd, Item *item, Item **new_item);
/// Treat UNKNOWN result like FALSE because callers see no difference
bool ignore_unknown() const { return abort_on_null; }
bool equality_substitution_analyzer(uchar **) override { return true; }
};
/*
The class Item_equal is used to represent conjunctions of equality
predicates of the form field1 = field2, and field=const in where
conditions and on expressions.
All equality predicates of the form field1=field2 contained in a
conjunction are substituted for a sequence of items of this class.
An item of this class Item_equal(f1,f2,...fk) represents a
multiple equality f1=f2=...=fk.
If a conjunction contains predicates f1=f2 and f2=f3, a new item of
this class is created Item_equal(f1,f2,f3) representing the multiple
equality f1=f2=f3 that substitutes the above equality predicates in
the conjunction.
A conjunction of the predicates f2=f1 and f3=f1 and f3=f2 will be
substituted for the item representing the same multiple equality
f1=f2=f3.
An item Item_equal(f1,f2) can appear instead of a conjunction of
f2=f1 and f1=f2, or instead of just the predicate f1=f2.
An item of the class Item_equal inherits equalities from outer
conjunctive levels.
Suppose we have a where condition of the following form:
WHERE f1=f2 AND f3=f4 AND f3=f5 AND ... AND (...OR (f1=f3 AND ...)).
In this case:
f1=f2 will be substituted for Item_equal(f1,f2);
f3=f4 and f3=f5 will be substituted for Item_equal(f3,f4,f5);
f1=f3 will be substituted for Item_equal(f1,f2,f3,f4,f5);
An object of the class Item_equal can contain an optional constant
item c. Then it represents a multiple equality of the form
c=f1=...=fk.
Objects of the class Item_equal are used for the following:
1. An object Item_equal(t1.f1,...,tk.fk) allows us to consider any
pair of tables ti and tj as joined by an equi-condition.
Thus it provide us with additional access paths from table to table.
2. An object Item_equal(t1.f1,...,tk.fk) is applied to deduce new
SARGable predicates:
f1=...=fk AND P(fi) => f1=...=fk AND P(fi) AND P(fj).
It also can give us additional index scans and can allow us to
improve selectivity estimates.
3. An object Item_equal(t1.f1,...,tk.fk) is used to optimize the
selected execution plan for the query: if table ti is accessed
before the table tj then in any predicate P in the where condition
the occurrence of tj.fj is substituted for ti.fi. This can allow
an evaluation of the predicate at an earlier step.
When feature 1 is supported they say that join transitive closure
is employed.
When feature 2 is supported they say that search argument transitive
closure is employed.
Both features are usually supported by preprocessing original query and
adding additional predicates.
We do not just add predicates, we rather dynamically replace some
predicates that can not be used to access tables in the investigated
plan for those, obtained by substitution of some fields for equal fields,
that can be used.
Prepared Statements/Stored Procedures note: instances of class
Item_equal are created only at the time a PS/SP is executed and
are deleted in the end of execution. All changes made to these
objects need not be registered in the list of changes of the parse
tree and do not harm PS/SP re-execution.
Item equal objects are employed only at the optimize phase. Usually they are
not supposed to be evaluated. Yet in some cases we call the method val_int()
for them. We have to take care of restricting the predicate such an
object represents f1=f2= ...=fn to the projection of known fields fi1=...=fik.
*/
class Item_equal final : public Item_bool_func {
List<Item_field> fields; /* list of equal field items */
Item *const_item; /* optional constant item equal to fields items */
cmp_item *eval_item;
Arg_comparator cmp;
bool cond_false;
bool compare_as_dates;
public:
inline Item_equal()
: Item_bool_func(), const_item(0), eval_item(0), cond_false(0) {}
Item_equal(Item_field *f1, Item_field *f2);
Item_equal(Item *c, Item_field *f);
Item_equal(Item_equal *item_equal);
~Item_equal() override { destroy(eval_item); }
inline Item *get_const() { return const_item; }
void set_const(Item *c) { const_item = c; }
bool compare_const(THD *thd, Item *c);
bool add(THD *thd, Item *c, Item_field *f);
bool add(THD *thd, Item *c);
void add(Item_field *f);
uint members();
bool contains(const Field *field) const;
/**
Get the first field of multiple equality, use for semantic checking.
@retval First field in the multiple equality.
*/
Item_field *get_first() { return fields.head(); }
Item_field *get_subst_item(const Item_field *field);
bool merge(THD *thd, Item_equal *item);
bool update_const(THD *thd);
enum Functype functype() const override { return MULT_EQUAL_FUNC; }
longlong val_int() override;
const char *func_name() const override { return "multiple equal"; }
optimize_type select_optimize(const THD *) override { return OPTIMIZE_EQUAL; }
virtual bool cast_incompatible_args(uchar *) override {
// Multiple equality nodes (Item_equal) should have been
// converted back to simple equalities (Item_func_eq) by
// substitute_for_best_equal_field before cast nodes are injected.
DBUG_ASSERT(false);
return false;
}
/**
Order field items in multiple equality according to a sorting criteria.
The function perform ordering of the field items in the Item_equal
object according to the criteria determined by the cmp callback parameter.
If cmp(item_field1,item_field2,arg)<0 than item_field1 must be
placed after item_field2.
The function sorts field items by the exchange sort algorithm.
The list of field items is looked through and whenever two neighboring
members follow in a wrong order they are swapped. This is performed
again and again until we get all members in a right order.
@param compare function to compare field item
*/
template <typename Node_cmp_func>
void sort(Node_cmp_func compare) {
fields.sort(compare);
}
friend class Item_equal_iterator;
bool resolve_type(THD *) override;
bool fix_fields(THD *thd, Item **ref) override;
void update_used_tables() override;
bool walk(Item_processor processor, enum_walk walk, uchar *arg) override;
Item *transform(Item_transformer transformer, uchar *arg) override;
void print(const THD *thd, String *str,
enum_query_type query_type) const override;
const CHARSET_INFO *compare_collation() const override {
return fields.head()->collation.collation;
}
bool equality_substitution_analyzer(uchar **) override { return true; }
Item *equality_substitution_transformer(uchar *arg) override;
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
Item *m_const_folding[2]; ///< temporary area used for constant folding
private:
void check_covering_prefix_keys();
};
class COND_EQUAL {
public:
uint max_members; /* max number of members the current level
list and all lower level lists */
COND_EQUAL *upper_levels; /* multiple equalities of upper and levels */
List<Item_equal> current_level; /* list of multiple equalities of
the current and level */
COND_EQUAL() { upper_levels = 0; }
};
class Item_equal_iterator : public List_iterator_fast<Item_field> {
public:
inline Item_equal_iterator(Item_equal &item_equal)
: List_iterator_fast<Item_field>(item_equal.fields) {}
inline Item_field *operator++(int) {
Item_field *item = (*(List_iterator_fast<Item_field> *)this)++;
return item;
}
inline void rewind(void) { List_iterator_fast<Item_field>::rewind(); }
};
class Item_cond_and final : public Item_cond {
public:
COND_EQUAL cond_equal; /* contains list of Item_equal objects for
the current and level and reference
to multiple equalities of upper and levels */
Item_cond_and() : Item_cond() {}
Item_cond_and(Item *i1, Item *i2) : Item_cond(i1, i2) {}
Item_cond_and(const POS &pos, Item *i1, Item *i2) : Item_cond(pos, i1, i2) {}
Item_cond_and(THD *thd, Item_cond_and *item) : Item_cond(thd, item) {}
Item_cond_and(List<Item> &list_arg) : Item_cond(list_arg) {}
enum Functype functype() const override { return COND_AND_FUNC; }
longlong val_int() override;
const char *func_name() const override { return "and"; }
Item *copy_andor_structure(THD *thd) override {
Item_cond_and *item;
if ((item = new Item_cond_and(thd, this)))
item->copy_andor_arguments(thd, this);
return item;
}
Item *truth_transformer(THD *, Bool_test) override;
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
bool has_any_hash_join_condition(const table_map left_tables,
const QEP_TAB &right_table) const override;
bool has_any_non_equi_join_condition() const override;
};
class Item_cond_or final : public Item_cond {
public:
Item_cond_or() : Item_cond() {}
Item_cond_or(Item *i1, Item *i2) : Item_cond(i1, i2) {}
Item_cond_or(const POS &pos, Item *i1, Item *i2) : Item_cond(pos, i1, i2) {}
Item_cond_or(THD *thd, Item_cond_or *item) : Item_cond(thd, item) {}
Item_cond_or(List<Item> &list_arg) : Item_cond(list_arg) {}
enum Functype functype() const override { return COND_OR_FUNC; }
longlong val_int() override;
const char *func_name() const override { return "or"; }
Item *copy_andor_structure(THD *thd) override {
Item_cond_or *item;
if ((item = new Item_cond_or(thd, this)))
item->copy_andor_arguments(thd, this);
return item;
}
Item *truth_transformer(THD *, Bool_test) override;
bool gc_subst_analyzer(uchar **) override { return true; }
float get_filtering_effect(THD *thd, table_map filter_for_table,
table_map read_tables,
const MY_BITMAP *fields_to_ignore,
double rows_in_table) override;
};
/// Builds condition: (a AND b) IS TRUE
inline Item *and_conds(Item *a, Item *b) {
if (!b) return a;
if (!a) return b;
Item *item = new Item_cond_and(a, b);
if (item == nullptr) return nullptr;
item->apply_is_true();
return item;
}
longlong get_datetime_value(THD *thd, Item ***item_arg, Item **cache_arg,
const Item *warn_item, bool *is_null);
// TODO: the next two functions should be moved to sql_time.{h,cc}
bool get_mysql_time_from_str_no_warn(THD *thd, String *str, MYSQL_TIME *l_time,
MYSQL_TIME_STATUS *status);
bool get_mysql_time_from_str(THD *thd, String *str,
enum_mysql_timestamp_type warn_type,
const char *warn_name, MYSQL_TIME *l_time);
/*
These need definitions from this file but the variables are defined
in mysqld.h. The variables really belong in this component, but for
the time being we leave them in mysqld.cc to avoid merge problems.
*/
extern Eq_creator eq_creator;
extern Equal_creator equal_creator;
extern Ne_creator ne_creator;
extern Gt_creator gt_creator;
extern Lt_creator lt_creator;
extern Ge_creator ge_creator;
extern Le_creator le_creator;
#endif /* ITEM_CMPFUNC_INCLUDED */