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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-05-04 18:07:14 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-05-04 18:07:14 +0000
commita175314c3e5827eb193872241446f2f8f5c9d33c (patch)
treecd3d60ca99ae00829c52a6ca79150a5b6e62528b /sql/sql_lex.cc
parentInitial commit. (diff)
downloadmariadb-10.5-a175314c3e5827eb193872241446f2f8f5c9d33c.tar.xz
mariadb-10.5-a175314c3e5827eb193872241446f2f8f5c9d33c.zip
Adding upstream version 1:10.5.12.upstream/1%10.5.12upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to '')
-rw-r--r--sql/sql_lex.cc11635
1 files changed, 11635 insertions, 0 deletions
diff --git a/sql/sql_lex.cc b/sql/sql_lex.cc
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+/* Copyright (c) 2000, 2019, Oracle and/or its affiliates.
+ Copyright (c) 2009, 2021, MariaDB Corporation.
+
+ This program is free software; you can redistribute it and/or modify
+ it under the terms of the GNU General Public License as published by
+ the Free Software Foundation; version 2 of the License.
+
+ This program is distributed in the hope that it will be useful,
+ but WITHOUT ANY WARRANTY; without even the implied warranty of
+ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
+ GNU General Public License for more details.
+
+ You should have received a copy of the GNU General Public License
+ along with this program; if not, write to the Free Software
+ Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1335 USA */
+
+
+/* A lexical scanner on a temporary buffer with a yacc interface */
+
+#define MYSQL_LEX 1
+#include "mariadb.h"
+#include "sql_priv.h"
+#include "sql_class.h" // sql_lex.h: SQLCOM_END
+#include "sql_lex.h"
+#include "sql_parse.h" // add_to_list
+#include "item_create.h"
+#include <m_ctype.h>
+#include <hash.h>
+#include "sp_head.h"
+#include "sp.h"
+#include "sql_select.h"
+#include "sql_cte.h"
+#include "sql_signal.h"
+#include "sql_derived.h"
+#include "sql_truncate.h" // Sql_cmd_truncate_table
+#include "sql_admin.h" // Sql_cmd_analyze/Check..._table
+#include "sql_partition.h"
+#include "sql_partition_admin.h" // Sql_cmd_alter_table_*_part
+#include "event_parse_data.h"
+
+void LEX::parse_error(uint err_number)
+{
+ thd->parse_error(err_number);
+}
+
+
+/**
+ LEX_STRING constant for null-string to be used in parser and other places.
+*/
+const LEX_STRING empty_lex_str= {(char *) "", 0};
+const LEX_CSTRING null_clex_str= {NULL, 0};
+const LEX_CSTRING empty_clex_str= {"", 0};
+const LEX_CSTRING star_clex_str= {"*", 1};
+const LEX_CSTRING param_clex_str= {"?", 1};
+
+
+/**
+ Helper action for a case expression statement (the expr in 'CASE expr').
+ This helper is used for 'searched' cases only.
+ @param lex the parser lex context
+ @param expr the parsed expression
+ @return 0 on success
+*/
+
+int sp_expr_lex::case_stmt_action_expr()
+{
+ int case_expr_id= spcont->register_case_expr();
+ sp_instr_set_case_expr *i;
+
+ if (spcont->push_case_expr_id(case_expr_id))
+ return 1;
+
+ i= new (thd->mem_root)
+ sp_instr_set_case_expr(sphead->instructions(), spcont, case_expr_id,
+ get_item(), this);
+
+ sphead->add_cont_backpatch(i);
+ return sphead->add_instr(i);
+}
+
+/**
+ Helper action for a case when condition.
+ This helper is used for both 'simple' and 'searched' cases.
+ @param lex the parser lex context
+ @param when the parsed expression for the WHEN clause
+ @param simple true for simple cases, false for searched cases
+*/
+
+int sp_expr_lex::case_stmt_action_when(bool simple)
+{
+ uint ip= sphead->instructions();
+ sp_instr_jump_if_not *i;
+ Item_case_expr *var;
+ Item *expr;
+
+ if (simple)
+ {
+ var= new (thd->mem_root)
+ Item_case_expr(thd, spcont->get_current_case_expr_id());
+
+#ifdef DBUG_ASSERT_EXISTS
+ if (var)
+ {
+ var->m_sp= sphead;
+ }
+#endif
+
+ expr= new (thd->mem_root) Item_func_eq(thd, var, get_item());
+ i= new (thd->mem_root) sp_instr_jump_if_not(ip, spcont, expr, this);
+ }
+ else
+ i= new (thd->mem_root) sp_instr_jump_if_not(ip, spcont, get_item(), this);
+
+ /*
+ BACKPATCH: Registering forward jump from
+ "case_stmt_action_when" to "case_stmt_action_then"
+ (jump_if_not from instruction 2 to 5, 5 to 8 ... in the example)
+ */
+
+ return
+ !MY_TEST(i) ||
+ sphead->push_backpatch(thd, i, spcont->push_label(thd, &empty_clex_str, 0)) ||
+ sphead->add_cont_backpatch(i) ||
+ sphead->add_instr(i);
+}
+
+/**
+ Helper action for a case then statements.
+ This helper is used for both 'simple' and 'searched' cases.
+ @param lex the parser lex context
+*/
+
+int LEX::case_stmt_action_then()
+{
+ uint ip= sphead->instructions();
+ sp_instr_jump *i= new (thd->mem_root) sp_instr_jump(ip, spcont);
+ if (!MY_TEST(i) || sphead->add_instr(i))
+ return 1;
+
+ /*
+ BACKPATCH: Resolving forward jump from
+ "case_stmt_action_when" to "case_stmt_action_then"
+ (jump_if_not from instruction 2 to 5, 5 to 8 ... in the example)
+ */
+
+ sphead->backpatch(spcont->pop_label());
+
+ /*
+ BACKPATCH: Registering forward jump from
+ "case_stmt_action_then" to after END CASE
+ (jump from instruction 4 to 12, 7 to 12 ... in the example)
+ */
+
+ return sphead->push_backpatch(thd, i, spcont->last_label());
+}
+
+
+/**
+ Helper action for a SET statement.
+ Used to push a system variable into the assignment list.
+
+ @param tmp the system variable with base name
+ @param var_type the scope of the variable
+ @param val the value being assigned to the variable
+
+ @return TRUE if error, FALSE otherwise.
+*/
+
+bool
+LEX::set_system_variable(enum enum_var_type var_type,
+ sys_var *sysvar, const Lex_ident_sys_st *base_name,
+ Item *val)
+{
+ set_var *setvar;
+
+ /* No AUTOCOMMIT from a stored function or trigger. */
+ if (spcont && sysvar == Sys_autocommit_ptr)
+ sphead->m_flags|= sp_head::HAS_SET_AUTOCOMMIT_STMT;
+
+ if (val && val->type() == Item::FIELD_ITEM &&
+ ((Item_field*)val)->table_name.str)
+ {
+ my_error(ER_WRONG_TYPE_FOR_VAR, MYF(0), sysvar->name.str);
+ return TRUE;
+ }
+
+ if (!(setvar= new (thd->mem_root) set_var(thd, var_type, sysvar,
+ base_name, val)))
+ return TRUE;
+
+ return var_list.push_back(setvar, thd->mem_root);
+}
+
+
+/**
+ Helper action for a SET statement.
+ Used to SET a field of NEW row.
+
+ @param name the field name
+ @param val the value being assigned to the row
+
+ @return TRUE if error, FALSE otherwise.
+*/
+
+bool LEX::set_trigger_new_row(const LEX_CSTRING *name, Item *val)
+{
+ Item_trigger_field *trg_fld;
+ sp_instr_set_trigger_field *sp_fld;
+
+ /* QQ: Shouldn't this be field's default value ? */
+ if (! val)
+ val= new (thd->mem_root) Item_null(thd);
+
+ DBUG_ASSERT(trg_chistics.action_time == TRG_ACTION_BEFORE &&
+ (trg_chistics.event == TRG_EVENT_INSERT ||
+ trg_chistics.event == TRG_EVENT_UPDATE));
+
+ trg_fld= new (thd->mem_root)
+ Item_trigger_field(thd, current_context(),
+ Item_trigger_field::NEW_ROW,
+ *name, UPDATE_ACL, FALSE);
+
+ if (unlikely(trg_fld == NULL))
+ return TRUE;
+
+ sp_fld= new (thd->mem_root)
+ sp_instr_set_trigger_field(sphead->instructions(),
+ spcont, trg_fld, val, this);
+
+ if (unlikely(sp_fld == NULL))
+ return TRUE;
+
+ /*
+ Let us add this item to list of all Item_trigger_field
+ objects in trigger.
+ */
+ trg_table_fields.link_in_list(trg_fld, &trg_fld->next_trg_field);
+
+ return sphead->add_instr(sp_fld);
+}
+
+
+/**
+ Create an object to represent a SP variable in the Item-hierarchy.
+
+ @param name The SP variable name.
+ @param spvar The SP variable (optional).
+ @param start_in_q Start position of the SP variable name in the query.
+ @param end_in_q End position of the SP variable name in the query.
+
+ @remark If spvar is not specified, the name is used to search for the
+ variable in the parse-time context. If the variable does not
+ exist, a error is set and NULL is returned to the caller.
+
+ @return An Item_splocal object representing the SP variable, or NULL on error.
+*/
+Item_splocal*
+LEX::create_item_for_sp_var(const Lex_ident_cli_st *cname, sp_variable *spvar)
+{
+ const Sp_rcontext_handler *rh;
+ Item_splocal *item;
+ const char *start_in_q= cname->pos();
+ const char *end_in_q= cname->end();
+ uint pos_in_q, len_in_q;
+ Lex_ident_sys name(thd, cname);
+
+ if (name.is_null())
+ return NULL; // EOM
+
+ /* If necessary, look for the variable. */
+ if (spcont && !spvar)
+ spvar= find_variable(&name, &rh);
+
+ if (!spvar)
+ {
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), name.str);
+ return NULL;
+ }
+
+ DBUG_ASSERT(spcont && spvar);
+
+ /* Position and length of the SP variable name in the query. */
+ pos_in_q= (uint)(start_in_q - sphead->m_tmp_query);
+ len_in_q= (uint)(end_in_q - start_in_q);
+
+ item= new (thd->mem_root)
+ Item_splocal(thd, rh, &name, spvar->offset, spvar->type_handler(),
+ pos_in_q, len_in_q);
+
+#ifdef DBUG_ASSERT_EXISTS
+ if (item)
+ item->m_sp= sphead;
+#endif
+
+ return item;
+}
+
+
+/**
+ Helper to resolve the SQL:2003 Syntax exception 1) in <in predicate>.
+ See SQL:2003, Part 2, section 8.4 <in predicate>, Note 184, page 383.
+ This function returns the proper item for the SQL expression
+ <code>left [NOT] IN ( expr )</code>
+ @param thd the current thread
+ @param left the in predicand
+ @param equal true for IN predicates, false for NOT IN predicates
+ @param expr first and only expression of the in value list
+ @return an expression representing the IN predicate.
+*/
+Item* handle_sql2003_note184_exception(THD *thd, Item* left, bool equal,
+ Item *expr)
+{
+ /*
+ Relevant references for this issue:
+ - SQL:2003, Part 2, section 8.4 <in predicate>, page 383,
+ - SQL:2003, Part 2, section 7.2 <row value expression>, page 296,
+ - SQL:2003, Part 2, section 6.3 <value expression primary>, page 174,
+ - SQL:2003, Part 2, section 7.15 <subquery>, page 370,
+ - SQL:2003 Feature F561, "Full value expressions".
+
+ The exception in SQL:2003 Note 184 means:
+ Item_singlerow_subselect, which corresponds to a <scalar subquery>,
+ should be re-interpreted as an Item_in_subselect, which corresponds
+ to a <table subquery> when used inside an <in predicate>.
+
+ Our reading of Note 184 is reccursive, so that all:
+ - IN (( <subquery> ))
+ - IN ((( <subquery> )))
+ - IN '('^N <subquery> ')'^N
+ - etc
+ should be interpreted as a <table subquery>, no matter how deep in the
+ expression the <subquery> is.
+ */
+
+ Item *result;
+
+ DBUG_ENTER("handle_sql2003_note184_exception");
+
+ if (expr->type() == Item::SUBSELECT_ITEM)
+ {
+ Item_subselect *expr2 = (Item_subselect*) expr;
+
+ if (expr2->substype() == Item_subselect::SINGLEROW_SUBS)
+ {
+ Item_singlerow_subselect *expr3 = (Item_singlerow_subselect*) expr2;
+ st_select_lex *subselect;
+
+ /*
+ Implement the mandated change, by altering the semantic tree:
+ left IN Item_singlerow_subselect(subselect)
+ is modified to
+ left IN (subselect)
+ which is represented as
+ Item_in_subselect(left, subselect)
+ */
+ subselect= expr3->invalidate_and_restore_select_lex();
+ result= new (thd->mem_root) Item_in_subselect(thd, left, subselect);
+
+ if (! equal)
+ result = negate_expression(thd, result);
+
+ DBUG_RETURN(result);
+ }
+ }
+
+ if (equal)
+ result= new (thd->mem_root) Item_func_eq(thd, left, expr);
+ else
+ result= new (thd->mem_root) Item_func_ne(thd, left, expr);
+
+ DBUG_RETURN(result);
+}
+
+/**
+ Create a separate LEX for each assignment if in SP.
+
+ If we are in SP we want have own LEX for each assignment.
+ This is mostly because it is hard for several sp_instr_set
+ and sp_instr_set_trigger instructions share one LEX.
+ (Well, it is theoretically possible but adds some extra
+ overhead on preparation for execution stage and IMO less
+ robust).
+
+ QQ: May be we should simply prohibit group assignments in SP?
+
+ @see sp_create_assignment_instr
+
+ @param thd Thread context
+ @param pos The position in the raw SQL buffer
+*/
+
+
+bool sp_create_assignment_lex(THD *thd, const char *pos)
+{
+ if (thd->lex->sphead)
+ {
+ sp_lex_local *new_lex;
+ if (!(new_lex= new (thd->mem_root) sp_lex_set_var(thd, thd->lex)) ||
+ new_lex->main_select_push())
+ return true;
+ new_lex->sphead->m_tmp_query= pos;
+ return thd->lex->sphead->reset_lex(thd, new_lex);
+ }
+ else
+ if (thd->lex->main_select_push(false))
+ return true;
+ return false;
+}
+
+
+/**
+ Create a SP instruction for a SET assignment.
+
+ @see sp_create_assignment_lex
+
+ @param thd - Thread context
+ @param no_lookahead - True if the parser has no lookahead
+ @param need_set_keyword - if a SET statement "SET a=10",
+ or a direct assignment overwise "a:=10"
+ @return false if success, true otherwise.
+*/
+
+bool sp_create_assignment_instr(THD *thd, bool no_lookahead,
+ bool need_set_keyword)
+{
+ LEX *lex= thd->lex;
+
+ if (lex->sphead)
+ {
+ if (!lex->var_list.is_empty())
+ {
+ /*
+ - Every variable assignment from the same SET command, e.g.:
+ SET @var1=expr1, @var2=expr2;
+ produce each own sp_create_assignment_instr() call
+ lex->var_list.elements is 1 in this case.
+ - This query:
+ SET TRANSACTION READ ONLY, ISOLATION LEVEL SERIALIZABLE;
+ in translated to:
+ SET tx_read_only=1, tx_isolation=ISO_SERIALIZABLE;
+ but produces a single sp_create_assignment_instr() call
+ which includes the query fragment covering both options.
+ */
+ DBUG_ASSERT(lex->var_list.elements >= 1 && lex->var_list.elements <= 2);
+ /*
+ sql_mode=ORACLE's direct assignment of a global variable
+ is not possible by the grammar.
+ */
+ DBUG_ASSERT(lex->option_type != OPT_GLOBAL || need_set_keyword);
+ /*
+ We have assignment to user or system variable or
+ option setting, so we should construct sp_instr_stmt
+ for it.
+ */
+ Lex_input_stream *lip= &thd->m_parser_state->m_lip;
+
+ /*
+ Extract the query statement from the tokenizer. The
+ end is either lip->ptr, if there was no lookahead,
+ lip->tok_end otherwise.
+ */
+ static const LEX_CSTRING setlc= { STRING_WITH_LEN("SET ") };
+ static const LEX_CSTRING setgl= { STRING_WITH_LEN("SET GLOBAL ") };
+ const char *qend= no_lookahead ? lip->get_ptr() : lip->get_tok_end();
+ Lex_cstring qbuf(lex->sphead->m_tmp_query, qend);
+ if (lex->new_sp_instr_stmt(thd,
+ lex->option_type == OPT_GLOBAL ? setgl :
+ need_set_keyword ? setlc :
+ null_clex_str,
+ qbuf))
+ return true;
+ }
+ lex->pop_select();
+ if (lex->check_main_unit_semantics())
+ {
+ /*
+ "lex" can be referrenced by:
+ - sp_instr_set SET a= expr;
+ - sp_instr_set_row_field SET r.a= expr;
+ - sp_instr_stmt (just generated above) SET @a= expr;
+ In this case, "lex" is fully owned by sp_instr_xxx and it will
+ be deleted by the destructor ~sp_instr_xxx().
+ So we should remove "lex" from the stack sp_head::m_lex,
+ to avoid double free.
+ Note, in case "lex" is not owned by any sp_instr_xxx,
+ it's also safe to remove it from the stack right now.
+ So we can remove it unconditionally, without testing lex->sp_lex_in_use.
+ */
+ lex->sphead->restore_lex(thd);
+ return true;
+ }
+ enum_var_type inner_option_type= lex->option_type;
+ if (lex->sphead->restore_lex(thd))
+ return true;
+ /* Copy option_type to outer lex in case it has changed. */
+ thd->lex->option_type= inner_option_type;
+ }
+ else
+ lex->pop_select();
+ return false;
+}
+
+
+void LEX::add_key_to_list(LEX_CSTRING *field_name,
+ enum Key::Keytype type, bool check_exists)
+{
+ Key *key;
+ MEM_ROOT *mem_root= thd->mem_root;
+ key= new (mem_root)
+ Key(type, &null_clex_str, HA_KEY_ALG_UNDEF, false,
+ DDL_options(check_exists ?
+ DDL_options::OPT_IF_NOT_EXISTS :
+ DDL_options::OPT_NONE));
+ key->columns.push_back(new (mem_root) Key_part_spec(field_name, 0),
+ mem_root);
+ alter_info.key_list.push_back(key, mem_root);
+}
+
+
+bool LEX::add_alter_list(LEX_CSTRING name, Virtual_column_info *expr,
+ bool exists)
+{
+ MEM_ROOT *mem_root= thd->mem_root;
+ Alter_column *ac= new (mem_root) Alter_column(name, expr, exists);
+ if (unlikely(ac == NULL))
+ return true;
+ alter_info.alter_list.push_back(ac, mem_root);
+ alter_info.flags|= ALTER_CHANGE_COLUMN_DEFAULT;
+ return false;
+}
+
+
+bool LEX::add_alter_list(LEX_CSTRING name, LEX_CSTRING new_name, bool exists)
+{
+ Alter_column *ac= new (thd->mem_root) Alter_column(name, new_name, exists);
+ if (unlikely(ac == NULL))
+ return true;
+ alter_info.alter_list.push_back(ac, thd->mem_root);
+ alter_info.flags|= ALTER_RENAME_COLUMN;
+ return false;
+}
+
+
+void LEX::init_last_field(Column_definition *field,
+ const LEX_CSTRING *field_name,
+ const CHARSET_INFO *cs)
+{
+ last_field= field;
+
+ field->field_name= *field_name;
+
+ /* reset LEX fields that are used in Create_field::set_and_check() */
+ charset= cs;
+}
+
+
+bool LEX::set_bincmp(CHARSET_INFO *cs, bool bin)
+{
+ /*
+ if charset is NULL - we're parsing a field declaration.
+ we cannot call find_bin_collation for a field here, because actual
+ field charset is determined in get_sql_field_charset() much later.
+ so we only set a flag.
+ */
+ if (!charset)
+ {
+ charset= cs;
+ last_field->flags|= bin ? BINCMP_FLAG : 0;
+ return false;
+ }
+
+ charset= bin ? find_bin_collation(cs ? cs : charset)
+ : cs ? cs : charset;
+ return charset == NULL;
+}
+
+
+Virtual_column_info *add_virtual_expression(THD *thd, Item *expr)
+{
+ Virtual_column_info *v= new (thd->mem_root) Virtual_column_info();
+ if (unlikely(!v))
+ return 0;
+ v->expr= expr;
+ v->utf8= 0; /* connection charset */
+ return v;
+}
+
+
+
+/**
+ @note The order of the elements of this array must correspond to
+ the order of elements in enum_binlog_stmt_unsafe.
+*/
+const int
+Query_tables_list::binlog_stmt_unsafe_errcode[BINLOG_STMT_UNSAFE_COUNT] =
+{
+ ER_BINLOG_UNSAFE_LIMIT,
+ ER_BINLOG_UNSAFE_INSERT_DELAYED,
+ ER_BINLOG_UNSAFE_SYSTEM_TABLE,
+ ER_BINLOG_UNSAFE_AUTOINC_COLUMNS,
+ ER_BINLOG_UNSAFE_UDF,
+ ER_BINLOG_UNSAFE_SYSTEM_VARIABLE,
+ ER_BINLOG_UNSAFE_SYSTEM_FUNCTION,
+ ER_BINLOG_UNSAFE_NONTRANS_AFTER_TRANS,
+ ER_BINLOG_UNSAFE_MULTIPLE_ENGINES_AND_SELF_LOGGING_ENGINE,
+ ER_BINLOG_UNSAFE_MIXED_STATEMENT,
+ ER_BINLOG_UNSAFE_INSERT_IGNORE_SELECT,
+ ER_BINLOG_UNSAFE_INSERT_SELECT_UPDATE,
+ ER_BINLOG_UNSAFE_WRITE_AUTOINC_SELECT,
+ ER_BINLOG_UNSAFE_REPLACE_SELECT,
+ ER_BINLOG_UNSAFE_CREATE_IGNORE_SELECT,
+ ER_BINLOG_UNSAFE_CREATE_REPLACE_SELECT,
+ ER_BINLOG_UNSAFE_CREATE_SELECT_AUTOINC,
+ ER_BINLOG_UNSAFE_UPDATE_IGNORE,
+ ER_BINLOG_UNSAFE_INSERT_TWO_KEYS,
+ ER_BINLOG_UNSAFE_AUTOINC_NOT_FIRST
+};
+
+
+/* Longest standard keyword name */
+
+#define TOCK_NAME_LENGTH 24
+
+/*
+ The following data is based on the latin1 character set, and is only
+ used when comparing keywords
+*/
+
+static uchar to_upper_lex[]=
+{
+ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15,
+ 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
+ 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47,
+ 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63,
+ 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79,
+ 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95,
+ 96, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79,
+ 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90,123,124,125,126,127,
+ 128,129,130,131,132,133,134,135,136,137,138,139,140,141,142,143,
+ 144,145,146,147,148,149,150,151,152,153,154,155,156,157,158,159,
+ 160,161,162,163,164,165,166,167,168,169,170,171,172,173,174,175,
+ 176,177,178,179,180,181,182,183,184,185,186,187,188,189,190,191,
+ 192,193,194,195,196,197,198,199,200,201,202,203,204,205,206,207,
+ 208,209,210,211,212,213,214,215,216,217,218,219,220,221,222,223,
+ 192,193,194,195,196,197,198,199,200,201,202,203,204,205,206,207,
+ 208,209,210,211,212,213,214,247,216,217,218,219,220,221,222,255
+};
+
+/*
+ Names of the index hints (for error messages). Keep in sync with
+ index_hint_type
+*/
+
+const char * index_hint_type_name[] =
+{
+ "IGNORE INDEX",
+ "USE INDEX",
+ "FORCE INDEX"
+};
+
+inline int lex_casecmp(const char *s, const char *t, uint len)
+{
+ while (len-- != 0 &&
+ to_upper_lex[(uchar) *s++] == to_upper_lex[(uchar) *t++]) ;
+ return (int) len+1;
+}
+
+#include <lex_hash.h>
+
+
+void lex_init(void)
+{
+ uint i;
+ DBUG_ENTER("lex_init");
+ for (i=0 ; i < array_elements(symbols) ; i++)
+ symbols[i].length=(uchar) strlen(symbols[i].name);
+ for (i=0 ; i < array_elements(sql_functions) ; i++)
+ sql_functions[i].length=(uchar) strlen(sql_functions[i].name);
+
+ DBUG_VOID_RETURN;
+}
+
+
+void lex_free(void)
+{ // Call this when daemon ends
+ DBUG_ENTER("lex_free");
+ DBUG_VOID_RETURN;
+}
+
+/**
+ Initialize lex object for use in fix_fields and parsing.
+
+ SYNOPSIS
+ init_lex_with_single_table()
+ @param thd The thread object
+ @param table The table object
+ @return Operation status
+ @retval TRUE An error occurred, memory allocation error
+ @retval FALSE Ok
+
+ DESCRIPTION
+ This function is used to initialize a lex object on the
+ stack for use by fix_fields and for parsing. In order to
+ work properly it also needs to initialize the
+ Name_resolution_context object of the lexer.
+ Finally it needs to set a couple of variables to ensure
+ proper functioning of fix_fields.
+*/
+
+int
+init_lex_with_single_table(THD *thd, TABLE *table, LEX *lex)
+{
+ TABLE_LIST *table_list;
+ Table_ident *table_ident;
+ SELECT_LEX *select_lex= lex->first_select_lex();
+ Name_resolution_context *context= &select_lex->context;
+ /*
+ We will call the parser to create a part_info struct based on the
+ partition string stored in the frm file.
+ We will use a local lex object for this purpose. However we also
+ need to set the Name_resolution_object for this lex object. We
+ do this by using add_table_to_list where we add the table that
+ we're working with to the Name_resolution_context.
+ */
+ thd->lex= lex;
+ lex_start(thd);
+ context->init();
+ if (unlikely((!(table_ident= new Table_ident(thd,
+ &table->s->db,
+ &table->s->table_name,
+ TRUE)))) ||
+ (unlikely(!(table_list= select_lex->add_table_to_list(thd,
+ table_ident,
+ NULL,
+ 0)))))
+ return TRUE;
+ context->resolve_in_table_list_only(table_list);
+ lex->use_only_table_context= TRUE;
+ lex->context_analysis_only|= CONTEXT_ANALYSIS_ONLY_VCOL_EXPR;
+ select_lex->cur_pos_in_select_list= UNDEF_POS;
+ table->map= 1; //To ensure correct calculation of const item
+ table_list->table= table;
+ table_list->cacheable_table= false;
+ lex->create_last_non_select_table= table_list;
+ return FALSE;
+}
+
+/**
+ End use of local lex with single table
+
+ SYNOPSIS
+ end_lex_with_single_table()
+ @param thd The thread object
+ @param table The table object
+ @param old_lex The real lex object connected to THD
+
+ DESCRIPTION
+ This function restores the real lex object after calling
+ init_lex_with_single_table and also restores some table
+ variables temporarily set.
+*/
+
+void
+end_lex_with_single_table(THD *thd, TABLE *table, LEX *old_lex)
+{
+ LEX *lex= thd->lex;
+ table->map= 0;
+ table->get_fields_in_item_tree= FALSE;
+ lex_end(lex);
+ thd->lex= old_lex;
+}
+
+
+void
+st_parsing_options::reset()
+{
+ allows_variable= TRUE;
+ lookup_keywords_after_qualifier= false;
+}
+
+
+/**
+ Perform initialization of Lex_input_stream instance.
+
+ Basically, a buffer for pre-processed query. This buffer should be large
+ enough to keep multi-statement query. The allocation is done once in
+ Lex_input_stream::init() in order to prevent memory pollution when
+ the server is processing large multi-statement queries.
+*/
+
+bool Lex_input_stream::init(THD *thd,
+ char* buff,
+ size_t length)
+{
+ DBUG_EXECUTE_IF("bug42064_simulate_oom",
+ DBUG_SET("+d,simulate_out_of_memory"););
+
+ m_cpp_buf= (char*) thd->alloc(length + 1);
+
+ DBUG_EXECUTE_IF("bug42064_simulate_oom",
+ DBUG_SET("-d,bug42064_simulate_oom"););
+
+ if (m_cpp_buf == NULL)
+ return true;
+
+ m_thd= thd;
+ reset(buff, length);
+
+ return false;
+}
+
+
+/**
+ Prepare Lex_input_stream instance state for use for handling next SQL statement.
+
+ It should be called between two statements in a multi-statement query.
+ The operation resets the input stream to the beginning-of-parse state,
+ but does not reallocate m_cpp_buf.
+*/
+
+void
+Lex_input_stream::reset(char *buffer, size_t length)
+{
+ yylineno= 1;
+ lookahead_token= -1;
+ lookahead_yylval= NULL;
+ m_ptr= buffer;
+ m_tok_start= NULL;
+ m_tok_end= NULL;
+ m_end_of_query= buffer + length;
+ m_tok_start_prev= NULL;
+ m_buf= buffer;
+ m_buf_length= length;
+ m_echo= TRUE;
+ m_cpp_tok_start= NULL;
+ m_cpp_tok_start_prev= NULL;
+ m_cpp_tok_end= NULL;
+ m_body_utf8= NULL;
+ m_cpp_utf8_processed_ptr= NULL;
+ next_state= MY_LEX_START;
+ found_semicolon= NULL;
+ ignore_space= MY_TEST(m_thd->variables.sql_mode & MODE_IGNORE_SPACE);
+ stmt_prepare_mode= FALSE;
+ multi_statements= TRUE;
+ in_comment=NO_COMMENT;
+ m_underscore_cs= NULL;
+ m_cpp_ptr= m_cpp_buf;
+}
+
+
+/**
+ The operation is called from the parser in order to
+ 1) designate the intention to have utf8 body;
+ 1) Indicate to the lexer that we will need a utf8 representation of this
+ statement;
+ 2) Determine the beginning of the body.
+
+ @param thd Thread context.
+ @param begin_ptr Pointer to the start of the body in the pre-processed
+ buffer.
+*/
+
+void Lex_input_stream::body_utf8_start(THD *thd, const char *begin_ptr)
+{
+ DBUG_ASSERT(begin_ptr);
+ DBUG_ASSERT(m_cpp_buf <= begin_ptr && begin_ptr <= m_cpp_buf + m_buf_length);
+
+ size_t body_utf8_length= get_body_utf8_maximum_length(thd);
+
+ m_body_utf8= (char *) thd->alloc(body_utf8_length + 1);
+ m_body_utf8_ptr= m_body_utf8;
+ *m_body_utf8_ptr= 0;
+
+ m_cpp_utf8_processed_ptr= begin_ptr;
+}
+
+
+size_t Lex_input_stream::get_body_utf8_maximum_length(THD *thd)
+{
+ /*
+ String literals can grow during escaping:
+ 1a. Character string '<TAB>' can grow to '\t', 3 bytes to 4 bytes growth.
+ 1b. Character string '1000 times <TAB>' grows from
+ 1002 to 2002 bytes (including quotes), which gives a little bit
+ less than 2 times growth.
+ "2" should be a reasonable multiplier that safely covers escaping needs.
+ */
+ return (m_buf_length / thd->variables.character_set_client->mbminlen) *
+ my_charset_utf8mb3_bin.mbmaxlen * 2/*for escaping*/;
+}
+
+
+/**
+ @brief The operation appends unprocessed part of pre-processed buffer till
+ the given pointer (ptr) and sets m_cpp_utf8_processed_ptr to end_ptr.
+
+ The idea is that some tokens in the pre-processed buffer (like character
+ set introducers) should be skipped.
+
+ Example:
+ CPP buffer: SELECT 'str1', _latin1 'str2';
+ m_cpp_utf8_processed_ptr -- points at the "SELECT ...";
+ In order to skip "_latin1", the following call should be made:
+ body_utf8_append(<pointer to "_latin1 ...">, <pointer to " 'str2'...">)
+
+ @param ptr Pointer in the pre-processed buffer, which specifies the
+ end of the chunk, which should be appended to the utf8
+ body.
+ @param end_ptr Pointer in the pre-processed buffer, to which
+ m_cpp_utf8_processed_ptr will be set in the end of the
+ operation.
+*/
+
+void Lex_input_stream::body_utf8_append(const char *ptr,
+ const char *end_ptr)
+{
+ DBUG_ASSERT(m_cpp_buf <= ptr && ptr <= m_cpp_buf + m_buf_length);
+ DBUG_ASSERT(m_cpp_buf <= end_ptr && end_ptr <= m_cpp_buf + m_buf_length);
+
+ if (!m_body_utf8)
+ return;
+
+ if (m_cpp_utf8_processed_ptr >= ptr)
+ return;
+
+ size_t bytes_to_copy= ptr - m_cpp_utf8_processed_ptr;
+
+ memcpy(m_body_utf8_ptr, m_cpp_utf8_processed_ptr, bytes_to_copy);
+ m_body_utf8_ptr += bytes_to_copy;
+ *m_body_utf8_ptr= 0;
+
+ m_cpp_utf8_processed_ptr= end_ptr;
+}
+
+/**
+ The operation appends unprocessed part of the pre-processed buffer till
+ the given pointer (ptr) and sets m_cpp_utf8_processed_ptr to ptr.
+
+ @param ptr Pointer in the pre-processed buffer, which specifies the end
+ of the chunk, which should be appended to the utf8 body.
+*/
+
+void Lex_input_stream::body_utf8_append(const char *ptr)
+{
+ body_utf8_append(ptr, ptr);
+}
+
+/**
+ The operation converts the specified text literal to the utf8 and appends
+ the result to the utf8-body.
+
+ @param thd Thread context.
+ @param txt Text literal.
+ @param txt_cs Character set of the text literal.
+ @param end_ptr Pointer in the pre-processed buffer, to which
+ m_cpp_utf8_processed_ptr will be set in the end of the
+ operation.
+*/
+
+void
+Lex_input_stream::body_utf8_append_ident(THD *thd,
+ const Lex_string_with_metadata_st *txt,
+ const char *end_ptr)
+{
+ if (!m_cpp_utf8_processed_ptr)
+ return;
+
+ LEX_CSTRING utf_txt;
+ thd->make_text_string_sys(&utf_txt, txt); // QQ: check return value?
+
+ /* NOTE: utf_txt.length is in bytes, not in symbols. */
+ memcpy(m_body_utf8_ptr, utf_txt.str, utf_txt.length);
+ m_body_utf8_ptr += utf_txt.length;
+ *m_body_utf8_ptr= 0;
+
+ m_cpp_utf8_processed_ptr= end_ptr;
+}
+
+
+
+
+extern "C" {
+
+/**
+ Escape a character. Consequently puts "escape" and "wc" characters into
+ the destination utf8 string.
+ @param cs - the character set (utf8)
+ @param escape - the escape character (backslash, single quote, double quote)
+ @param wc - the character to be escaped
+ @param str - the destination string
+ @param end - the end of the destination string
+ @returns - a code according to the wc_mb() convension.
+*/
+int my_wc_mb_utf8mb3_with_escape(CHARSET_INFO *cs, my_wc_t escape, my_wc_t wc,
+ uchar *str, uchar *end)
+{
+ DBUG_ASSERT(escape > 0);
+ if (str + 1 >= end)
+ return MY_CS_TOOSMALL2; // Not enough space, need at least two bytes.
+ *str= (uchar)escape;
+ int cnvres= my_charset_utf8mb3_handler.wc_mb(cs, wc, str + 1, end);
+ if (cnvres > 0)
+ return cnvres + 1; // The character was normally put
+ if (cnvres == MY_CS_ILUNI)
+ return MY_CS_ILUNI; // Could not encode "wc" (e.g. non-BMP character)
+ DBUG_ASSERT(cnvres <= MY_CS_TOOSMALL);
+ return cnvres - 1; // Not enough space
+}
+
+
+/**
+ Optionally escape a character.
+ If "escape" is non-zero, then both "escape" and "wc" are put to
+ the destination string. Otherwise, only "wc" is put.
+ @param cs - the character set (utf8)
+ @param wc - the character to be optionally escaped
+ @param escape - the escape character, or 0
+ @param ewc - the escaped replacement of "wc" (e.g. 't' for '\t')
+ @param str - the destination string
+ @param end - the end of the destination string
+ @returns - a code according to the wc_mb() conversion.
+*/
+int my_wc_mb_utf8mb3_opt_escape(CHARSET_INFO *cs,
+ my_wc_t wc, my_wc_t escape, my_wc_t ewc,
+ uchar *str, uchar *end)
+{
+ return escape ? my_wc_mb_utf8mb3_with_escape(cs, escape, ewc, str, end) :
+ my_charset_utf8mb3_handler.wc_mb(cs, wc, str, end);
+}
+
+/**
+ Encode a character with optional backlash escaping and quote escaping.
+ Quote marks are escaped using another quote mark.
+ Additionally, if "escape" is non-zero, then special characters are
+ also escaped using "escape".
+ Otherwise (if "escape" is zero, e.g. in case of MODE_NO_BACKSLASH_ESCAPES),
+ then special characters are not escaped and handled as normal characters.
+
+ @param cs - the character set (utf8)
+ @param wc - the character to be encoded
+ @param str - the destination string
+ @param end - the end of the destination string
+ @param sep - the string delimiter (e.g. ' or ")
+ @param escape - the escape character (backslash, or 0)
+ @returns - a code according to the wc_mb() convension.
+*/
+int my_wc_mb_utf8mb3_escape(CHARSET_INFO *cs, my_wc_t wc,
+ uchar *str, uchar *end,
+ my_wc_t sep, my_wc_t escape)
+{
+ DBUG_ASSERT(escape == 0 || escape == '\\');
+ DBUG_ASSERT(sep == '"' || sep == '\'');
+ switch (wc) {
+ case 0: return my_wc_mb_utf8mb3_opt_escape(cs, wc, escape, '0', str, end);
+ case '\t': return my_wc_mb_utf8mb3_opt_escape(cs, wc, escape, 't', str, end);
+ case '\r': return my_wc_mb_utf8mb3_opt_escape(cs, wc, escape, 'r', str, end);
+ case '\n': return my_wc_mb_utf8mb3_opt_escape(cs, wc, escape, 'n', str, end);
+ case '\032': return my_wc_mb_utf8mb3_opt_escape(cs, wc, escape, 'Z', str, end);
+ case '\'':
+ case '\"':
+ if (wc == sep)
+ return my_wc_mb_utf8mb3_with_escape(cs, wc, wc, str, end);
+ }
+ return my_charset_utf8mb3_handler.wc_mb(cs, wc, str, end); // No escaping needed
+}
+
+
+/** wc_mb() compatible routines for all sql_mode and delimiter combinations */
+int my_wc_mb_utf8mb3_escape_single_quote_and_backslash(CHARSET_INFO *cs,
+ my_wc_t wc,
+ uchar *str, uchar *end)
+{
+ return my_wc_mb_utf8mb3_escape(cs, wc, str, end, '\'', '\\');
+}
+
+
+int my_wc_mb_utf8mb3_escape_double_quote_and_backslash(CHARSET_INFO *cs,
+ my_wc_t wc,
+ uchar *str, uchar *end)
+{
+ return my_wc_mb_utf8mb3_escape(cs, wc, str, end, '"', '\\');
+}
+
+
+int my_wc_mb_utf8mb3_escape_single_quote(CHARSET_INFO *cs, my_wc_t wc,
+ uchar *str, uchar *end)
+{
+ return my_wc_mb_utf8mb3_escape(cs, wc, str, end, '\'', 0);
+}
+
+
+int my_wc_mb_utf8mb3_escape_double_quote(CHARSET_INFO *cs, my_wc_t wc,
+ uchar *str, uchar *end)
+{
+ return my_wc_mb_utf8mb3_escape(cs, wc, str, end, '"', 0);
+}
+
+}; // End of extern "C"
+
+
+/**
+ Get an escaping function, depending on the current sql_mode and the
+ string separator.
+*/
+my_charset_conv_wc_mb
+Lex_input_stream::get_escape_func(THD *thd, my_wc_t sep) const
+{
+ return thd->backslash_escapes() ?
+ (sep == '"' ? my_wc_mb_utf8mb3_escape_double_quote_and_backslash:
+ my_wc_mb_utf8mb3_escape_single_quote_and_backslash) :
+ (sep == '"' ? my_wc_mb_utf8mb3_escape_double_quote:
+ my_wc_mb_utf8mb3_escape_single_quote);
+}
+
+
+/**
+ Append a text literal to the end of m_body_utf8.
+ The string is escaped according to the current sql_mode and the
+ string delimiter (e.g. ' or ").
+
+ @param thd - current THD
+ @param txt - the string to be appended to m_body_utf8.
+ Note, the string must be already unescaped.
+ @param cs - the character set of the string
+ @param end_ptr - m_cpp_utf8_processed_ptr will be set to this value
+ (see body_utf8_append_ident for details)
+ @param sep - the string delimiter (single or double quote)
+*/
+void Lex_input_stream::body_utf8_append_escape(THD *thd,
+ const LEX_CSTRING *txt,
+ CHARSET_INFO *cs,
+ const char *end_ptr,
+ my_wc_t sep)
+{
+ DBUG_ASSERT(sep == '\'' || sep == '"');
+ if (!m_cpp_utf8_processed_ptr)
+ return;
+ uint errors;
+ /**
+ We previously alloced m_body_utf8 to be able to store the query with all
+ strings properly escaped. See get_body_utf8_maximum_length().
+ So here we have guaranteedly enough space to append any string literal
+ with escaping. Passing txt->length*2 as "available space" is always safe.
+ For better safety purposes we could calculate get_body_utf8_maximum_length()
+ every time we append a string, but this would affect performance negatively,
+ so let's check that we don't get beyond the allocated buffer in
+ debug build only.
+ */
+ DBUG_ASSERT(m_body_utf8 + get_body_utf8_maximum_length(thd) >=
+ m_body_utf8_ptr + txt->length * 2);
+ uint32 cnv_length= my_convert_using_func(m_body_utf8_ptr, txt->length * 2,
+ &my_charset_utf8mb3_general_ci,
+ get_escape_func(thd, sep),
+ txt->str, txt->length,
+ cs, cs->cset->mb_wc,
+ &errors);
+ m_body_utf8_ptr+= cnv_length;
+ *m_body_utf8_ptr= 0;
+ m_cpp_utf8_processed_ptr= end_ptr;
+}
+
+
+void Lex_input_stream::add_digest_token(uint token, LEX_YYSTYPE yylval)
+{
+ if (m_digest != NULL)
+ {
+ m_digest= digest_add_token(m_digest, token, yylval);
+ }
+}
+
+void Lex_input_stream::reduce_digest_token(uint token_left, uint token_right)
+{
+ if (m_digest != NULL)
+ {
+ m_digest= digest_reduce_token(m_digest, token_left, token_right);
+ }
+}
+
+/**
+ lex starting operations for builtin select collected together
+*/
+
+void SELECT_LEX::lex_start(LEX *plex)
+{
+ SELECT_LEX_UNIT *unit= &plex->unit;
+ /* 'parent_lex' is used in init_query() so it must be before it. */
+ parent_lex= plex;
+ init_query();
+ master= unit;
+ prev= &unit->slave;
+ link_next= slave= next= 0;
+ link_prev= (st_select_lex_node**)&(plex->all_selects_list);
+ DBUG_ASSERT(!group_list_ptrs);
+ select_number= 1;
+ in_sum_expr=0;
+ ftfunc_list_alloc.empty();
+ ftfunc_list= &ftfunc_list_alloc;
+ group_list.empty();
+ order_list.empty();
+ gorder_list.empty();
+}
+
+void lex_start(THD *thd)
+{
+ DBUG_ENTER("lex_start");
+ thd->lex->start(thd);
+ DBUG_VOID_RETURN;
+}
+
+
+/*
+ This is called before every query that is to be parsed.
+ Because of this, it's critical to not do too much things here.
+ (We already do too much here)
+*/
+
+void LEX::start(THD *thd_arg)
+{
+ DBUG_ENTER("LEX::start");
+ DBUG_PRINT("info", ("This: %p thd_arg->lex: %p", this, thd_arg->lex));
+
+ thd= unit.thd= thd_arg;
+ stmt_lex= this; // default, should be rewritten for VIEWs And CTEs
+
+ DBUG_ASSERT(!explain);
+
+ builtin_select.lex_start(this);
+ lex_options= 0;
+ context_stack.empty();
+ //empty select_stack
+ select_stack_top= 0;
+ unit.init_query();
+ current_select_number= 0;
+ curr_with_clause= 0;
+ with_clauses_list= 0;
+ with_clauses_list_last_next= &with_clauses_list;
+ clone_spec_offset= 0;
+ create_view= NULL;
+ field_list.empty();
+ value_list.empty();
+ update_list.empty();
+ set_var_list.empty();
+ param_list.empty();
+ view_list.empty();
+ with_persistent_for_clause= FALSE;
+ column_list= NULL;
+ index_list= NULL;
+ prepared_stmt.lex_start();
+ auxiliary_table_list.empty();
+ unit.next= unit.master= unit.link_next= unit.return_to= 0;
+ unit.prev= unit.link_prev= 0;
+ unit.slave= current_select= all_selects_list= &builtin_select;
+ sql_cache= LEX::SQL_CACHE_UNSPECIFIED;
+ describe= 0;
+ analyze_stmt= 0;
+ explain_json= false;
+ context_analysis_only= 0;
+ derived_tables= 0;
+ with_cte_resolution= false;
+ only_cte_resolution= false;
+ safe_to_cache_query= 1;
+ parsing_options.reset();
+ empty_field_list_on_rset= 0;
+ part_info= 0;
+ m_sql_cmd= NULL;
+ duplicates= DUP_ERROR;
+ ignore= 0;
+ spname= NULL;
+ spcont= NULL;
+ proc_list.first= 0;
+ escape_used= FALSE;
+ default_used= FALSE;
+ query_tables= 0;
+ reset_query_tables_list(FALSE);
+ clause_that_disallows_subselect= NULL;
+ selects_allow_into= FALSE;
+ selects_allow_procedure= FALSE;
+ use_only_table_context= FALSE;
+ parse_vcol_expr= FALSE;
+ check_exists= FALSE;
+ create_info.lex_start();
+ verbose= 0;
+
+ name= null_clex_str;
+ event_parse_data= NULL;
+ profile_options= PROFILE_NONE;
+ nest_level= 0;
+ builtin_select.nest_level_base= &unit;
+ allow_sum_func.clear_all();
+ in_sum_func= NULL;
+
+ used_tables= 0;
+ table_type= TABLE_TYPE_UNKNOWN;
+ reset_slave_info.all= false;
+ limit_rows_examined= 0;
+ limit_rows_examined_cnt= ULONGLONG_MAX;
+ var_list.empty();
+ stmt_var_list.empty();
+ proc_list.elements=0;
+
+ save_group_list.empty();
+ save_order_list.empty();
+ win_ref= NULL;
+ win_frame= NULL;
+ frame_top_bound= NULL;
+ frame_bottom_bound= NULL;
+ win_spec= NULL;
+
+ vers_conditions.empty();
+ period_conditions.empty();
+
+ is_lex_started= TRUE;
+
+ next_is_main= FALSE;
+ next_is_down= FALSE;
+
+ wild= 0;
+ exchange= 0;
+
+ DBUG_VOID_RETURN;
+}
+
+void lex_end(LEX *lex)
+{
+ DBUG_ENTER("lex_end");
+ DBUG_PRINT("enter", ("lex: %p", lex));
+
+ lex_unlock_plugins(lex);
+ lex_end_nops(lex);
+
+ DBUG_VOID_RETURN;
+}
+
+void lex_unlock_plugins(LEX *lex)
+{
+ DBUG_ENTER("lex_unlock_plugins");
+
+ /* release used plugins */
+ if (lex->plugins.elements) /* No function call and no mutex if no plugins. */
+ {
+ plugin_unlock_list(0, (plugin_ref*)lex->plugins.buffer,
+ lex->plugins.elements);
+ }
+ reset_dynamic(&lex->plugins);
+ DBUG_VOID_RETURN;
+}
+
+/*
+ Don't delete lex->sphead, it'll be needed for EXECUTE.
+ Note that of all statements that populate lex->sphead
+ only SQLCOM_COMPOUND can be PREPAREd
+
+ MASTER INFO parameters (or state) is normally cleared towards the end
+ of a statement. But in case of PS, the state needs to be preserved during
+ its lifetime and should only be cleared on PS close or deallocation.
+*/
+void lex_end_nops(LEX *lex)
+{
+ DBUG_ENTER("lex_end_nops");
+ sp_head::destroy(lex->sphead);
+ lex->sphead= NULL;
+
+ /* Reset LEX_MASTER_INFO */
+ lex->mi.reset(lex->sql_command == SQLCOM_CHANGE_MASTER);
+ delete_dynamic(&lex->delete_gtid_domain);
+
+ DBUG_VOID_RETURN;
+}
+
+Yacc_state::~Yacc_state()
+{
+ if (yacc_yyss)
+ {
+ my_free(yacc_yyss);
+ my_free(yacc_yyvs);
+ }
+}
+
+int Lex_input_stream::find_keyword(Lex_ident_cli_st *kwd,
+ uint len, bool function)
+{
+ const char *tok= m_tok_start;
+
+ SYMBOL *symbol= get_hash_symbol(tok, len, function);
+ if (symbol)
+ {
+ kwd->set_keyword(tok, len);
+ DBUG_ASSERT(tok >= get_buf());
+ DBUG_ASSERT(tok < get_end_of_query());
+
+ if (m_thd->variables.sql_mode & MODE_ORACLE)
+ {
+ switch (symbol->tok) {
+ case BEGIN_MARIADB_SYM: return BEGIN_ORACLE_SYM;
+ case BLOB_MARIADB_SYM: return BLOB_ORACLE_SYM;
+ case BODY_MARIADB_SYM: return BODY_ORACLE_SYM;
+ case CLOB_MARIADB_SYM: return CLOB_ORACLE_SYM;
+ case CONTINUE_MARIADB_SYM: return CONTINUE_ORACLE_SYM;
+ case DECLARE_MARIADB_SYM: return DECLARE_ORACLE_SYM;
+ case DECODE_MARIADB_SYM: return DECODE_ORACLE_SYM;
+ case ELSEIF_MARIADB_SYM: return ELSEIF_ORACLE_SYM;
+ case ELSIF_MARIADB_SYM: return ELSIF_ORACLE_SYM;
+ case EXCEPTION_MARIADB_SYM: return EXCEPTION_ORACLE_SYM;
+ case EXIT_MARIADB_SYM: return EXIT_ORACLE_SYM;
+ case GOTO_MARIADB_SYM: return GOTO_ORACLE_SYM;
+ case NUMBER_MARIADB_SYM: return NUMBER_ORACLE_SYM;
+ case OTHERS_MARIADB_SYM: return OTHERS_ORACLE_SYM;
+ case PACKAGE_MARIADB_SYM: return PACKAGE_ORACLE_SYM;
+ case RAISE_MARIADB_SYM: return RAISE_ORACLE_SYM;
+ case RAW_MARIADB_SYM: return RAW_ORACLE_SYM;
+ case RETURN_MARIADB_SYM: return RETURN_ORACLE_SYM;
+ case ROWTYPE_MARIADB_SYM: return ROWTYPE_ORACLE_SYM;
+ case VARCHAR2_MARIADB_SYM: return VARCHAR2_ORACLE_SYM;
+ }
+ }
+
+ if ((symbol->tok == NOT_SYM) &&
+ (m_thd->variables.sql_mode & MODE_HIGH_NOT_PRECEDENCE))
+ return NOT2_SYM;
+ if ((symbol->tok == OR2_SYM) &&
+ (m_thd->variables.sql_mode & MODE_PIPES_AS_CONCAT))
+ {
+ return (m_thd->variables.sql_mode & MODE_ORACLE) ?
+ ORACLE_CONCAT_SYM : MYSQL_CONCAT_SYM;
+ }
+
+ return symbol->tok;
+ }
+ return 0;
+}
+
+/*
+ Check if name is a keyword
+
+ SYNOPSIS
+ is_keyword()
+ name checked name (must not be empty)
+ len length of checked name
+
+ RETURN VALUES
+ 0 name is a keyword
+ 1 name isn't a keyword
+*/
+
+bool is_keyword(const char *name, uint len)
+{
+ DBUG_ASSERT(len != 0);
+ return get_hash_symbol(name,len,0)!=0;
+}
+
+/**
+ Check if name is a sql function
+
+ @param name checked name
+
+ @return is this a native function or not
+ @retval 0 name is a function
+ @retval 1 name isn't a function
+*/
+
+bool is_lex_native_function(const LEX_CSTRING *name)
+{
+ DBUG_ASSERT(name != NULL);
+ return (get_hash_symbol(name->str, (uint) name->length, 1) != 0);
+}
+
+
+bool is_native_function(THD *thd, const LEX_CSTRING *name)
+{
+ if (find_native_function_builder(thd, name))
+ return true;
+
+ if (is_lex_native_function(name))
+ return true;
+
+ if (Type_handler::handler_by_name(thd, *name))
+ return true;
+
+ return false;
+}
+
+
+bool is_native_function_with_warn(THD *thd, const LEX_CSTRING *name)
+{
+ if (!is_native_function(thd, name))
+ return false;
+ /*
+ This warning will be printed when
+ [1] A client query is parsed,
+ [2] A stored function is loaded by db_load_routine.
+ Printing the warning for [2] is intentional, to cover the
+ following scenario:
+ - A user define a SF 'foo' using MySQL 5.N
+ - An application uses select foo(), and works.
+ - MySQL 5.{N+1} defines a new native function 'foo', as
+ part of a new feature.
+ - MySQL 5.{N+1} documentation is updated, and should mention
+ that there is a potential incompatible change in case of
+ existing stored function named 'foo'.
+ - The user deploys 5.{N+1}. At this point, 'select foo()'
+ means something different, and the user code is most likely
+ broken (it's only safe if the code is 'select db.foo()').
+ With a warning printed when the SF is loaded (which has to
+ occur before the call), the warning will provide a hint
+ explaining the root cause of a later failure of 'select foo()'.
+ With no warning printed, the user code will fail with no
+ apparent reason.
+ Printing a warning each time db_load_routine is executed for
+ an ambiguous function is annoying, since that can happen a lot,
+ but in practice should not happen unless there *are* name
+ collisions.
+ If a collision exists, it should not be silenced but fixed.
+ */
+ push_warning_printf(thd,
+ Sql_condition::WARN_LEVEL_NOTE,
+ ER_NATIVE_FCT_NAME_COLLISION,
+ ER_THD(thd, ER_NATIVE_FCT_NAME_COLLISION),
+ name->str);
+ return true;
+}
+
+
+/* make a copy of token before ptr and set yytoklen */
+
+LEX_CSTRING Lex_input_stream::get_token(uint skip, uint length)
+{
+ LEX_CSTRING tmp;
+ yyUnget(); // ptr points now after last token char
+ tmp.length= length;
+ tmp.str= m_thd->strmake(m_tok_start + skip, tmp.length);
+
+ m_cpp_text_start= m_cpp_tok_start + skip;
+ m_cpp_text_end= m_cpp_text_start + tmp.length;
+
+ return tmp;
+}
+
+
+static size_t
+my_unescape(CHARSET_INFO *cs, char *to, const char *str, const char *end,
+ int sep, bool backslash_escapes)
+{
+ char *start= to;
+ for ( ; str != end ; str++)
+ {
+#ifdef USE_MB
+ int l;
+ if (cs->use_mb() && (l= my_ismbchar(cs, str, end)))
+ {
+ while (l--)
+ *to++ = *str++;
+ str--;
+ continue;
+ }
+#endif
+ if (backslash_escapes && *str == '\\' && str + 1 != end)
+ {
+ switch(*++str) {
+ case 'n':
+ *to++='\n';
+ break;
+ case 't':
+ *to++= '\t';
+ break;
+ case 'r':
+ *to++ = '\r';
+ break;
+ case 'b':
+ *to++ = '\b';
+ break;
+ case '0':
+ *to++= 0; // Ascii null
+ break;
+ case 'Z': // ^Z must be escaped on Win32
+ *to++='\032';
+ break;
+ case '_':
+ case '%':
+ *to++= '\\'; // remember prefix for wildcard
+ /* Fall through */
+ default:
+ *to++= *str;
+ break;
+ }
+ }
+ else if (*str == sep)
+ *to++= *str++; // Two ' or "
+ else
+ *to++ = *str;
+ }
+ *to= 0;
+ return to - start;
+}
+
+
+size_t
+Lex_input_stream::unescape(CHARSET_INFO *cs, char *to,
+ const char *str, const char *end,
+ int sep)
+{
+ return my_unescape(cs, to, str, end, sep, m_thd->backslash_escapes());
+}
+
+
+/*
+ Return an unescaped text literal without quotes
+ Fix sometimes to do only one scan of the string
+*/
+
+bool Lex_input_stream::get_text(Lex_string_with_metadata_st *dst, uint sep,
+ int pre_skip, int post_skip)
+{
+ uchar c;
+ uint found_escape=0;
+ CHARSET_INFO *cs= m_thd->charset();
+ bool is_8bit= false;
+
+ while (! eof())
+ {
+ c= yyGet();
+ if (c & 0x80)
+ is_8bit= true;
+#ifdef USE_MB
+ {
+ int l;
+ if (cs->use_mb() &&
+ (l = my_ismbchar(cs,
+ get_ptr() -1,
+ get_end_of_query()))) {
+ skip_binary(l-1);
+ continue;
+ }
+ }
+#endif
+ if (c == '\\' &&
+ !(m_thd->variables.sql_mode & MODE_NO_BACKSLASH_ESCAPES))
+ { // Escaped character
+ found_escape=1;
+ if (eof())
+ return true;
+ yySkip();
+ }
+ else if (c == sep)
+ {
+ if (c == yyGet()) // Check if two separators in a row
+ {
+ found_escape=1; // duplicate. Remember for delete
+ continue;
+ }
+ else
+ yyUnget();
+
+ /* Found end. Unescape and return string */
+ const char *str, *end;
+ char *to;
+
+ str= m_tok_start;
+ end= get_ptr();
+ /* Extract the text from the token */
+ str += pre_skip;
+ end -= post_skip;
+ DBUG_ASSERT(end >= str);
+
+ if (!(to= (char*) m_thd->alloc((uint) (end - str) + 1)))
+ {
+ dst->set(&empty_clex_str, 0, '\0');
+ return true; // Sql_alloc has set error flag
+ }
+
+ m_cpp_text_start= m_cpp_tok_start + pre_skip;
+ m_cpp_text_end= get_cpp_ptr() - post_skip;
+
+ if (!found_escape)
+ {
+ size_t len= (end - str);
+ memcpy(to, str, len);
+ to[len]= '\0';
+ dst->set(to, len, is_8bit, '\0');
+ }
+ else
+ {
+ size_t len= unescape(cs, to, str, end, sep);
+ dst->set(to, len, is_8bit, '\0');
+ }
+ return false;
+ }
+ }
+ return true; // unexpected end of query
+}
+
+
+/*
+** Calc type of integer; long integer, longlong integer or real.
+** Returns smallest type that match the string.
+** When using unsigned long long values the result is converted to a real
+** because else they will be unexpected sign changes because all calculation
+** is done with longlong or double.
+*/
+
+static const char *long_str="2147483647";
+static const uint long_len=10;
+static const char *signed_long_str="-2147483648";
+static const char *longlong_str="9223372036854775807";
+static const uint longlong_len=19;
+static const char *signed_longlong_str="-9223372036854775808";
+static const uint signed_longlong_len=19;
+static const char *unsigned_longlong_str="18446744073709551615";
+static const uint unsigned_longlong_len=20;
+
+static inline uint int_token(const char *str,uint length)
+{
+ if (length < long_len) // quick normal case
+ return NUM;
+ bool neg=0;
+
+ if (*str == '+') // Remove sign and pre-zeros
+ {
+ str++; length--;
+ }
+ else if (*str == '-')
+ {
+ str++; length--;
+ neg=1;
+ }
+ while (*str == '0' && length)
+ {
+ str++; length --;
+ }
+ if (length < long_len)
+ return NUM;
+
+ uint smaller,bigger;
+ const char *cmp;
+ if (neg)
+ {
+ if (length == long_len)
+ {
+ cmp= signed_long_str + 1;
+ smaller= NUM; // If <= signed_long_str
+ bigger= LONG_NUM; // If >= signed_long_str
+ }
+ else if (length < signed_longlong_len)
+ return LONG_NUM;
+ else if (length > signed_longlong_len)
+ return DECIMAL_NUM;
+ else
+ {
+ cmp= signed_longlong_str + 1;
+ smaller= LONG_NUM; // If <= signed_longlong_str
+ bigger=DECIMAL_NUM;
+ }
+ }
+ else
+ {
+ if (length == long_len)
+ {
+ cmp= long_str;
+ smaller=NUM;
+ bigger=LONG_NUM;
+ }
+ else if (length < longlong_len)
+ return LONG_NUM;
+ else if (length > longlong_len)
+ {
+ if (length > unsigned_longlong_len)
+ return DECIMAL_NUM;
+ cmp=unsigned_longlong_str;
+ smaller=ULONGLONG_NUM;
+ bigger=DECIMAL_NUM;
+ }
+ else
+ {
+ cmp=longlong_str;
+ smaller=LONG_NUM;
+ bigger= ULONGLONG_NUM;
+ }
+ }
+ while (*cmp && *cmp++ == *str++) ;
+ return ((uchar) str[-1] <= (uchar) cmp[-1]) ? smaller : bigger;
+}
+
+
+/**
+ Given a stream that is advanced to the first contained character in
+ an open comment, consume the comment. Optionally, if we are allowed,
+ recurse so that we understand comments within this current comment.
+
+ At this level, we do not support version-condition comments. We might
+ have been called with having just passed one in the stream, though. In
+ that case, we probably want to tolerate mundane comments inside. Thus,
+ the case for recursion.
+
+ @retval Whether EOF reached before comment is closed.
+*/
+bool Lex_input_stream::consume_comment(int remaining_recursions_permitted)
+{
+ // only one level of nested comments are allowed
+ DBUG_ASSERT(remaining_recursions_permitted == 0 ||
+ remaining_recursions_permitted == 1);
+ uchar c;
+ while (!eof())
+ {
+ c= yyGet();
+
+ if (remaining_recursions_permitted == 1)
+ {
+ if ((c == '/') && (yyPeek() == '*'))
+ {
+ yyUnput('('); // Replace nested "/*..." with "(*..."
+ yySkip(); // and skip "("
+
+ yySkip(); /* Eat asterisk */
+ if (consume_comment(0))
+ return true;
+
+ yyUnput(')'); // Replace "...*/" with "...*)"
+ yySkip(); // and skip ")"
+ continue;
+ }
+ }
+
+ if (c == '*')
+ {
+ if (yyPeek() == '/')
+ {
+ yySkip(); // Eat slash
+ return FALSE;
+ }
+ }
+
+ if (c == '\n')
+ yylineno++;
+ }
+
+ return TRUE;
+}
+
+
+/*
+ MYSQLlex remember the following states from the following MYSQLlex()
+
+ @param yylval [out] semantic value of the token being parsed (yylval)
+ @param thd THD
+
+ - MY_LEX_EOQ Found end of query
+ - MY_LEX_OPERATOR_OR_IDENT Last state was an ident, text or number
+ (which can't be followed by a signed number)
+*/
+
+int MYSQLlex(YYSTYPE *yylval, THD *thd)
+{
+ return thd->m_parser_state->m_lip.lex_token(yylval, thd);
+}
+
+
+int ORAlex(YYSTYPE *yylval, THD *thd)
+{
+ return thd->m_parser_state->m_lip.lex_token(yylval, thd);
+}
+
+
+int Lex_input_stream::lex_token(YYSTYPE *yylval, THD *thd)
+{
+ int token;
+ const int left_paren= (int) '(';
+
+ if (lookahead_token >= 0)
+ {
+ /*
+ The next token was already parsed in advance,
+ return it.
+ */
+ token= lookahead_token;
+ lookahead_token= -1;
+ *yylval= *(lookahead_yylval);
+ lookahead_yylval= NULL;
+ return token;
+ }
+
+ token= lex_one_token(yylval, thd);
+ add_digest_token(token, yylval);
+
+ SELECT_LEX *curr_sel= thd->lex->current_select;
+
+ switch(token) {
+ case WITH:
+ /*
+ Parsing 'WITH' 'ROLLUP' or 'WITH' 'CUBE' requires 2 look ups,
+ which makes the grammar LALR(2).
+ Replace by a single 'WITH_ROLLUP' or 'WITH_CUBE' token,
+ to transform the grammar into a LALR(1) grammar,
+ which sql_yacc.yy can process.
+ */
+ token= lex_one_token(yylval, thd);
+ add_digest_token(token, yylval);
+ switch(token) {
+ case CUBE_SYM:
+ return WITH_CUBE_SYM;
+ case ROLLUP_SYM:
+ return WITH_ROLLUP_SYM;
+ case SYSTEM:
+ return WITH_SYSTEM_SYM;
+ default:
+ /*
+ Save the token following 'WITH'
+ */
+ lookahead_yylval= yylval;
+ lookahead_token= token;
+ return WITH;
+ }
+ break;
+ case FOR_SYM:
+ /*
+ * Additional look-ahead to resolve doubtful cases like:
+ * SELECT ... FOR UPDATE
+ * SELECT ... FOR SYSTEM_TIME ... .
+ */
+ token= lex_one_token(yylval, thd);
+ add_digest_token(token, yylval);
+ switch(token) {
+ case SYSTEM_TIME_SYM:
+ return FOR_SYSTEM_TIME_SYM;
+ default:
+ /*
+ Save the token following 'FOR_SYM'
+ */
+ lookahead_yylval= yylval;
+ lookahead_token= token;
+ return FOR_SYM;
+ }
+ break;
+ case VALUES:
+ if (curr_sel &&
+ (curr_sel->parsing_place == BEFORE_OPT_LIST ||
+ curr_sel->parsing_place == AFTER_LIST))
+ {
+ curr_sel->parsing_place= NO_MATTER;
+ break;
+ }
+ if (curr_sel &&
+ (curr_sel->parsing_place == IN_UPDATE_ON_DUP_KEY ||
+ curr_sel->parsing_place == IN_PART_FUNC))
+ return VALUE_SYM;
+ token= lex_one_token(yylval, thd);
+ add_digest_token(token, yylval);
+ switch(token) {
+ case LESS_SYM:
+ return VALUES_LESS_SYM;
+ case IN_SYM:
+ return VALUES_IN_SYM;
+ default:
+ lookahead_yylval= yylval;
+ lookahead_token= token;
+ return VALUES;
+ }
+ case VALUE_SYM:
+ if (curr_sel &&
+ (curr_sel->parsing_place == BEFORE_OPT_LIST ||
+ curr_sel->parsing_place == AFTER_LIST))
+ {
+ curr_sel->parsing_place= NO_MATTER;
+ return VALUES;
+ }
+ break;
+ case PARTITION_SYM:
+ case SELECT_SYM:
+ case UNION_SYM:
+ if (curr_sel &&
+ (curr_sel->parsing_place == BEFORE_OPT_LIST ||
+ curr_sel->parsing_place == AFTER_LIST))
+ {
+ curr_sel->parsing_place= NO_MATTER;
+ }
+ break;
+ case left_paren:
+ if (!curr_sel ||
+ curr_sel->parsing_place != BEFORE_OPT_LIST)
+ return token;
+ token= lex_one_token(yylval, thd);
+ add_digest_token(token, yylval);
+ lookahead_yylval= yylval;
+ yylval= NULL;
+ lookahead_token= token;
+ curr_sel->parsing_place= NO_MATTER;
+ if (token == LIKE)
+ return LEFT_PAREN_LIKE;
+ if (token == WITH)
+ return LEFT_PAREN_WITH;
+ if (token != left_paren && token != SELECT_SYM && token != VALUES)
+ return LEFT_PAREN_ALT;
+ else
+ return left_paren;
+ break;
+ default:
+ break;
+ }
+ return token;
+}
+
+
+int Lex_input_stream::lex_one_token(YYSTYPE *yylval, THD *thd)
+{
+ uchar UNINIT_VAR(c);
+ bool comment_closed;
+ int tokval;
+ uint length;
+ enum my_lex_states state;
+ LEX *lex= thd->lex;
+ CHARSET_INFO *const cs= thd->charset();
+ const uchar *const state_map= cs->state_map;
+ const uchar *const ident_map= cs->ident_map;
+
+ start_token();
+ state= next_state;
+ next_state= MY_LEX_OPERATOR_OR_IDENT;
+ for (;;)
+ {
+ switch (state) {
+ case MY_LEX_OPERATOR_OR_IDENT: // Next is operator or keyword
+ case MY_LEX_START: // Start of token
+ // Skip starting whitespace
+ while(state_map[c= yyPeek()] == MY_LEX_SKIP)
+ {
+ if (c == '\n')
+ yylineno++;
+
+ yySkip();
+ }
+
+ /* Start of real token */
+ restart_token();
+ c= yyGet();
+ state= (enum my_lex_states) state_map[c];
+ break;
+ case MY_LEX_ESCAPE:
+ if (!eof() && yyGet() == 'N')
+ { // Allow \N as shortcut for NULL
+ yylval->lex_str.str= (char*) "\\N";
+ yylval->lex_str.length= 2;
+ return NULL_SYM;
+ }
+ /* Fall through */
+ case MY_LEX_CHAR: // Unknown or single char token
+ if (c == '%' && (m_thd->variables.sql_mode & MODE_ORACLE))
+ {
+ next_state= MY_LEX_START;
+ return PERCENT_ORACLE_SYM;
+ }
+ if (c == '[' && (m_thd->variables.sql_mode & MODE_MSSQL))
+ return scan_ident_delimited(thd, &yylval->ident_cli, ']');
+ /* Fall through */
+ case MY_LEX_SKIP: // This should not happen
+ if (c != ')')
+ next_state= MY_LEX_START; // Allow signed numbers
+ yylval->kwd.set_keyword(m_tok_start, 1);
+ return((int) c);
+
+ case MY_LEX_MINUS_OR_COMMENT:
+ if (yyPeek() == '-' &&
+ (my_isspace(cs,yyPeekn(1)) ||
+ my_iscntrl(cs,yyPeekn(1))))
+ {
+ state=MY_LEX_COMMENT;
+ break;
+ }
+ next_state= MY_LEX_START; // Allow signed numbers
+ return((int) c);
+
+ case MY_LEX_PLACEHOLDER:
+ /*
+ Check for a placeholder: it should not precede a possible identifier
+ because of binlogging: when a placeholder is replaced with
+ its value in a query for the binlog, the query must stay
+ grammatically correct.
+ */
+ next_state= MY_LEX_START; // Allow signed numbers
+ if (stmt_prepare_mode && !ident_map[(uchar) yyPeek()])
+ return(PARAM_MARKER);
+ return((int) c);
+
+ case MY_LEX_COMMA:
+ next_state= MY_LEX_START; // Allow signed numbers
+ /*
+ Warning:
+ This is a work around, to make the "remember_name" rule in
+ sql/sql_yacc.yy work properly.
+ The problem is that, when parsing "select expr1, expr2",
+ the code generated by bison executes the *pre* action
+ remember_name (see select_item) *before* actually parsing the
+ first token of expr2.
+ */
+ restart_token();
+ return((int) c);
+
+ case MY_LEX_IDENT_OR_NCHAR:
+ {
+ uint sep;
+ if (yyPeek() != '\'')
+ {
+ state= MY_LEX_IDENT;
+ break;
+ }
+ /* Found N'string' */
+ yySkip(); // Skip '
+ if (get_text(&yylval->lex_string_with_metadata, (sep= yyGetLast()), 2, 1))
+ {
+ state= MY_LEX_CHAR; // Read char by char
+ break;
+ }
+
+ body_utf8_append(m_cpp_text_start);
+ body_utf8_append_escape(thd, &yylval->lex_string_with_metadata,
+ national_charset_info,
+ m_cpp_text_end, sep);
+ return(NCHAR_STRING);
+ }
+ case MY_LEX_IDENT_OR_HEX:
+ if (yyPeek() == '\'')
+ { // Found x'hex-number'
+ state= MY_LEX_HEX_NUMBER;
+ break;
+ }
+ /* fall through */
+ case MY_LEX_IDENT_OR_BIN:
+ if (yyPeek() == '\'')
+ { // Found b'bin-number'
+ state= MY_LEX_BIN_NUMBER;
+ break;
+ }
+ /* fall through */
+ case MY_LEX_IDENT:
+ {
+ tokval= scan_ident_middle(thd, &yylval->ident_cli,
+ &yylval->charset, &state);
+ if (!tokval)
+ continue;
+ if (tokval == UNDERSCORE_CHARSET)
+ m_underscore_cs= yylval->charset;
+ return tokval;
+ }
+
+ case MY_LEX_IDENT_SEP: // Found ident and now '.'
+ yylval->lex_str.str= (char*) get_ptr();
+ yylval->lex_str.length= 1;
+ c= yyGet(); // should be '.'
+ if (lex->parsing_options.lookup_keywords_after_qualifier)
+ next_state= MY_LEX_IDENT_OR_KEYWORD;
+ else
+ next_state= MY_LEX_IDENT_START; // Next is ident (not keyword)
+ if (!ident_map[(uchar) yyPeek()]) // Probably ` or "
+ next_state= MY_LEX_START;
+ return((int) c);
+
+ case MY_LEX_NUMBER_IDENT: // number or ident which num-start
+ if (yyGetLast() == '0')
+ {
+ c= yyGet();
+ if (c == 'x')
+ {
+ while (my_isxdigit(cs, (c = yyGet()))) ;
+ if ((yyLength() >= 3) && !ident_map[c])
+ {
+ /* skip '0x' */
+ yylval->lex_str= get_token(2, yyLength() - 2);
+ return (HEX_NUM);
+ }
+ yyUnget();
+ state= MY_LEX_IDENT_START;
+ break;
+ }
+ else if (c == 'b')
+ {
+ while ((c= yyGet()) == '0' || c == '1')
+ ;
+ if ((yyLength() >= 3) && !ident_map[c])
+ {
+ /* Skip '0b' */
+ yylval->lex_str= get_token(2, yyLength() - 2);
+ return (BIN_NUM);
+ }
+ yyUnget();
+ state= MY_LEX_IDENT_START;
+ break;
+ }
+ yyUnget();
+ }
+
+ while (my_isdigit(cs, (c= yyGet()))) ;
+ if (!ident_map[c])
+ { // Can't be identifier
+ state=MY_LEX_INT_OR_REAL;
+ break;
+ }
+ if (c == 'e' || c == 'E')
+ {
+ // The following test is written this way to allow numbers of type 1e1
+ if (my_isdigit(cs, yyPeek()) ||
+ (c=(yyGet())) == '+' || c == '-')
+ { // Allow 1E+10
+ if (my_isdigit(cs, yyPeek())) // Number must have digit after sign
+ {
+ yySkip();
+ while (my_isdigit(cs, yyGet())) ;
+ yylval->lex_str= get_token(0, yyLength());
+ return(FLOAT_NUM);
+ }
+ }
+ /*
+ We've found:
+ - A sequence of digits
+ - Followed by 'e' or 'E'
+ - Followed by some byte XX which is not a known mantissa start,
+ and it's known to be a valid identifier part.
+ XX can be either a 8bit identifier character, or a multi-byte head.
+ */
+ yyUnget();
+ return scan_ident_start(thd, &yylval->ident_cli);
+ }
+ /*
+ We've found:
+ - A sequence of digits
+ - Followed by some character XX, which is neither 'e' nor 'E',
+ and it's known to be a valid identifier part.
+ XX can be a 8bit identifier character, or a multi-byte head.
+ */
+ yyUnget();
+ return scan_ident_start(thd, &yylval->ident_cli);
+
+ case MY_LEX_IDENT_START: // We come here after '.'
+ return scan_ident_start(thd, &yylval->ident_cli);
+
+ case MY_LEX_USER_VARIABLE_DELIMITER: // Found quote char
+ return scan_ident_delimited(thd, &yylval->ident_cli, m_tok_start[0]);
+
+ case MY_LEX_INT_OR_REAL: // Complete int or incomplete real
+ if (c != '.' || yyPeek() == '.')
+ {
+ /*
+ Found a complete integer number:
+ - the number is either not followed by a dot at all, or
+ - the number is followed by a double dot as in: FOR i IN 1..10
+ */
+ yylval->lex_str= get_token(0, yyLength());
+ return int_token(yylval->lex_str.str, (uint) yylval->lex_str.length);
+ }
+ // fall through
+ case MY_LEX_REAL: // Incomplete real number
+ while (my_isdigit(cs, c= yyGet())) ;
+
+ if (c == 'e' || c == 'E')
+ {
+ c= yyGet();
+ if (c == '-' || c == '+')
+ c= yyGet(); // Skip sign
+ if (!my_isdigit(cs, c))
+ { // No digit after sign
+ state= MY_LEX_CHAR;
+ break;
+ }
+ while (my_isdigit(cs, yyGet())) ;
+ yylval->lex_str= get_token(0, yyLength());
+ return(FLOAT_NUM);
+ }
+ yylval->lex_str= get_token(0, yyLength());
+ return(DECIMAL_NUM);
+
+ case MY_LEX_HEX_NUMBER: // Found x'hexstring'
+ yySkip(); // Accept opening '
+ while (my_isxdigit(cs, (c= yyGet()))) ;
+ if (c != '\'')
+ return(ABORT_SYM); // Illegal hex constant
+ yySkip(); // Accept closing '
+ length= yyLength(); // Length of hexnum+3
+ if ((length % 2) == 0)
+ return(ABORT_SYM); // odd number of hex digits
+ yylval->lex_str= get_token(2, // skip x'
+ length - 3); // don't count x' and last '
+ return HEX_STRING;
+
+ case MY_LEX_BIN_NUMBER: // Found b'bin-string'
+ yySkip(); // Accept opening '
+ while ((c= yyGet()) == '0' || c == '1')
+ ;
+ if (c != '\'')
+ return(ABORT_SYM); // Illegal hex constant
+ yySkip(); // Accept closing '
+ length= yyLength(); // Length of bin-num + 3
+ yylval->lex_str= get_token(2, // skip b'
+ length - 3); // don't count b' and last '
+ return (BIN_NUM);
+
+ case MY_LEX_CMP_OP: // Incomplete comparison operator
+ next_state= MY_LEX_START; // Allow signed numbers
+ if (state_map[(uchar) yyPeek()] == MY_LEX_CMP_OP ||
+ state_map[(uchar) yyPeek()] == MY_LEX_LONG_CMP_OP)
+ {
+ yySkip();
+ if ((tokval= find_keyword(&yylval->kwd, 2, 0)))
+ return(tokval);
+ yyUnget();
+ }
+ return(c);
+
+ case MY_LEX_LONG_CMP_OP: // Incomplete comparison operator
+ next_state= MY_LEX_START;
+ if (state_map[(uchar) yyPeek()] == MY_LEX_CMP_OP ||
+ state_map[(uchar) yyPeek()] == MY_LEX_LONG_CMP_OP)
+ {
+ yySkip();
+ if (state_map[(uchar) yyPeek()] == MY_LEX_CMP_OP)
+ {
+ yySkip();
+ if ((tokval= find_keyword(&yylval->kwd, 3, 0)))
+ return(tokval);
+ yyUnget();
+ }
+ if ((tokval= find_keyword(&yylval->kwd, 2, 0)))
+ return(tokval);
+ yyUnget();
+ }
+ return(c);
+
+ case MY_LEX_BOOL:
+ if (c != yyPeek())
+ {
+ state= MY_LEX_CHAR;
+ break;
+ }
+ yySkip();
+ tokval= find_keyword(&yylval->kwd, 2, 0); // Is a bool operator
+ next_state= MY_LEX_START; // Allow signed numbers
+ return(tokval);
+
+ case MY_LEX_STRING_OR_DELIMITER:
+ if (thd->variables.sql_mode & MODE_ANSI_QUOTES)
+ {
+ state= MY_LEX_USER_VARIABLE_DELIMITER;
+ break;
+ }
+ /* " used for strings */
+ /* fall through */
+ case MY_LEX_STRING: // Incomplete text string
+ {
+ uint sep;
+ if (get_text(&yylval->lex_string_with_metadata, (sep= yyGetLast()), 1, 1))
+ {
+ state= MY_LEX_CHAR; // Read char by char
+ break;
+ }
+ CHARSET_INFO *strcs= m_underscore_cs ? m_underscore_cs : cs;
+ body_utf8_append(m_cpp_text_start);
+
+ body_utf8_append_escape(thd, &yylval->lex_string_with_metadata,
+ strcs, m_cpp_text_end, sep);
+ m_underscore_cs= NULL;
+ return(TEXT_STRING);
+ }
+ case MY_LEX_COMMENT: // Comment
+ lex->lex_options|= OPTION_LEX_FOUND_COMMENT;
+ while ((c= yyGet()) != '\n' && c) ;
+ yyUnget(); // Safety against eof
+ state= MY_LEX_START; // Try again
+ break;
+ case MY_LEX_LONG_COMMENT: // Long C comment?
+ if (yyPeek() != '*')
+ {
+ state= MY_LEX_CHAR; // Probable division
+ break;
+ }
+ lex->lex_options|= OPTION_LEX_FOUND_COMMENT;
+ /* Reject '/' '*', since we might need to turn off the echo */
+ yyUnget();
+
+ save_in_comment_state();
+
+ if (yyPeekn(2) == '!' ||
+ (yyPeekn(2) == 'M' && yyPeekn(3) == '!'))
+ {
+ bool maria_comment_syntax= yyPeekn(2) == 'M';
+ in_comment= DISCARD_COMMENT;
+ /* Accept '/' '*' '!', but do not keep this marker. */
+ set_echo(FALSE);
+ yySkipn(maria_comment_syntax ? 4 : 3);
+
+ /*
+ The special comment format is very strict:
+ '/' '*' '!', followed by an optional 'M' and exactly
+ 1-2 digits (major), 2 digits (minor), then 2 digits (dot).
+ 32302 -> 3.23.02
+ 50032 -> 5.0.32
+ 50114 -> 5.1.14
+ 100000 -> 10.0.0
+ */
+ if ( my_isdigit(cs, yyPeekn(0))
+ && my_isdigit(cs, yyPeekn(1))
+ && my_isdigit(cs, yyPeekn(2))
+ && my_isdigit(cs, yyPeekn(3))
+ && my_isdigit(cs, yyPeekn(4))
+ )
+ {
+ ulong version;
+ uint length= 5;
+ char *end_ptr= (char*) get_ptr() + length;
+ int error;
+ if (my_isdigit(cs, yyPeekn(5)))
+ {
+ end_ptr++; // 6 digit number
+ length++;
+ }
+
+ version= (ulong) my_strtoll10(get_ptr(), &end_ptr, &error);
+
+ /*
+ MySQL-5.7 has new features and might have new SQL syntax that
+ MariaDB-10.0 does not understand. Ignore all versioned comments
+ with MySQL versions in the range 50700-999999, but
+ do not ignore MariaDB specific comments for the same versions.
+ */
+ if (version <= MYSQL_VERSION_ID &&
+ (version < 50700 || version > 99999 || maria_comment_syntax))
+ {
+ /* Accept 'M' 'm' 'm' 'd' 'd' */
+ yySkipn(length);
+ /* Expand the content of the special comment as real code */
+ set_echo(TRUE);
+ state=MY_LEX_START;
+ break; /* Do not treat contents as a comment. */
+ }
+ else
+ {
+#ifdef WITH_WSREP
+ if (WSREP(thd) && version == 99997 && wsrep_thd_is_local(thd))
+ {
+ WSREP_DEBUG("consistency check: %s", thd->query());
+ thd->wsrep_consistency_check= CONSISTENCY_CHECK_DECLARED;
+ yySkipn(5);
+ set_echo(TRUE);
+ state= MY_LEX_START;
+ break; /* Do not treat contents as a comment. */
+ }
+#endif /* WITH_WSREP */
+ /*
+ Patch and skip the conditional comment to avoid it
+ being propagated infinitely (eg. to a slave).
+ */
+ char *pcom= yyUnput(' ');
+ comment_closed= ! consume_comment(1);
+ if (! comment_closed)
+ {
+ *pcom= '!';
+ }
+ /* version allowed to have one level of comment inside. */
+ }
+ }
+ else
+ {
+ /* Not a version comment. */
+ state=MY_LEX_START;
+ set_echo(TRUE);
+ break;
+ }
+ }
+ else
+ {
+ in_comment= PRESERVE_COMMENT;
+ yySkip(); // Accept /
+ yySkip(); // Accept *
+ comment_closed= ! consume_comment(0);
+ /* regular comments can have zero comments inside. */
+ }
+ /*
+ Discard:
+ - regular '/' '*' comments,
+ - special comments '/' '*' '!' for a future version,
+ by scanning until we find a closing '*' '/' marker.
+
+ Nesting regular comments isn't allowed. The first
+ '*' '/' returns the parser to the previous state.
+
+ /#!VERSI oned containing /# regular #/ is allowed #/
+
+ Inside one versioned comment, another versioned comment
+ is treated as a regular discardable comment. It gets
+ no special parsing.
+ */
+
+ /* Unbalanced comments with a missing '*' '/' are a syntax error */
+ if (! comment_closed)
+ return (ABORT_SYM);
+ state = MY_LEX_START; // Try again
+ restore_in_comment_state();
+ break;
+ case MY_LEX_END_LONG_COMMENT:
+ if ((in_comment != NO_COMMENT) && yyPeek() == '/')
+ {
+ /* Reject '*' '/' */
+ yyUnget();
+ /* Accept '*' '/', with the proper echo */
+ set_echo(in_comment == PRESERVE_COMMENT);
+ yySkipn(2);
+ /* And start recording the tokens again */
+ set_echo(TRUE);
+ in_comment= NO_COMMENT;
+ state=MY_LEX_START;
+ }
+ else
+ state= MY_LEX_CHAR; // Return '*'
+ break;
+ case MY_LEX_SET_VAR: // Check if ':='
+ if (yyPeek() != '=')
+ {
+ next_state= MY_LEX_START;
+ if (m_thd->variables.sql_mode & MODE_ORACLE)
+ {
+ yylval->kwd.set_keyword(m_tok_start, 1);
+ return COLON_ORACLE_SYM;
+ }
+ return (int) ':';
+ }
+ yySkip();
+ return (SET_VAR);
+ case MY_LEX_SEMICOLON: // optional line terminator
+ state= MY_LEX_CHAR; // Return ';'
+ break;
+ case MY_LEX_EOL:
+ if (eof())
+ {
+ yyUnget(); // Reject the last '\0'
+ set_echo(FALSE);
+ yySkip();
+ set_echo(TRUE);
+ /* Unbalanced comments with a missing '*' '/' are a syntax error */
+ if (in_comment != NO_COMMENT)
+ return (ABORT_SYM);
+ next_state= MY_LEX_END; // Mark for next loop
+ return(END_OF_INPUT);
+ }
+ state=MY_LEX_CHAR;
+ break;
+ case MY_LEX_END:
+ next_state= MY_LEX_END;
+ return(0); // We found end of input last time
+
+ /* Actually real shouldn't start with . but allow them anyhow */
+ case MY_LEX_REAL_OR_POINT:
+ if (my_isdigit(cs, (c= yyPeek())))
+ state = MY_LEX_REAL; // Real
+ else if (c == '.')
+ {
+ yySkip();
+ return DOT_DOT_SYM;
+ }
+ else
+ {
+ state= MY_LEX_IDENT_SEP; // return '.'
+ yyUnget(); // Put back '.'
+ }
+ break;
+ case MY_LEX_USER_END: // end '@' of user@hostname
+ switch (state_map[(uchar) yyPeek()]) {
+ case MY_LEX_STRING:
+ case MY_LEX_USER_VARIABLE_DELIMITER:
+ case MY_LEX_STRING_OR_DELIMITER:
+ break;
+ case MY_LEX_USER_END:
+ next_state= MY_LEX_SYSTEM_VAR;
+ break;
+ default:
+ next_state= MY_LEX_HOSTNAME;
+ break;
+ }
+ yylval->lex_str.str= (char*) get_ptr() - 1;
+ yylval->lex_str.length= 1;
+ return((int) '@');
+ case MY_LEX_HOSTNAME: // end '@' of user@hostname
+ for (c= yyGet() ;
+ my_isalnum(cs, c) || c == '.' || c == '_' || c == '$';
+ c= yyGet()) ;
+ yylval->lex_str= get_token(0, yyLength());
+ return(LEX_HOSTNAME);
+ case MY_LEX_SYSTEM_VAR:
+ yylval->lex_str.str= (char*) get_ptr();
+ yylval->lex_str.length= 1;
+ yySkip(); // Skip '@'
+ next_state= (state_map[(uchar) yyPeek()] ==
+ MY_LEX_USER_VARIABLE_DELIMITER ?
+ MY_LEX_OPERATOR_OR_IDENT :
+ MY_LEX_IDENT_OR_KEYWORD);
+ return((int) '@');
+ case MY_LEX_IDENT_OR_KEYWORD:
+ /*
+ We come here when we have found two '@' in a row.
+ We should now be able to handle:
+ [(global | local | session) .]variable_name
+ */
+ return scan_ident_sysvar(thd, &yylval->ident_cli);
+ }
+ }
+}
+
+
+bool Lex_input_stream::get_7bit_or_8bit_ident(THD *thd, uchar *last_char)
+{
+ uchar c;
+ CHARSET_INFO *const cs= thd->charset();
+ const uchar *const ident_map= cs->ident_map;
+ bool is_8bit= false;
+ for ( ; ident_map[c= yyGet()]; )
+ {
+ if (c & 0x80)
+ is_8bit= true; // will convert
+ }
+ *last_char= c;
+ return is_8bit;
+}
+
+
+int Lex_input_stream::scan_ident_sysvar(THD *thd, Lex_ident_cli_st *str)
+{
+ uchar last_char;
+ uint length;
+ int tokval;
+ bool is_8bit;
+ DBUG_ASSERT(m_tok_start == m_ptr);
+
+ is_8bit= get_7bit_or_8bit_ident(thd, &last_char);
+
+ if (last_char == '.')
+ next_state= MY_LEX_IDENT_SEP;
+ if (!(length= yyLength()))
+ return ABORT_SYM; // Names must be nonempty.
+ if ((tokval= find_keyword(str, length, 0)))
+ {
+ yyUnget(); // Put back 'c'
+ return tokval; // Was keyword
+ }
+
+ yyUnget(); // ptr points now after last token char
+ str->set_ident(m_tok_start, length, is_8bit);
+
+ m_cpp_text_start= m_cpp_tok_start;
+ m_cpp_text_end= m_cpp_text_start + length;
+ body_utf8_append(m_cpp_text_start);
+ body_utf8_append_ident(thd, str, m_cpp_text_end);
+
+ return is_8bit ? IDENT_QUOTED : IDENT;
+}
+
+
+/*
+ We can come here if different parsing stages:
+ - In an identifier chain:
+ SELECT t1.cccc FROM t1;
+ (when the "cccc" part starts)
+ In this case both m_tok_start and m_ptr point to "cccc".
+ - When a sequence of digits has changed to something else,
+ therefore the token becomes an identifier rather than a number:
+ SELECT 12345_6 FROM t1;
+ In this case m_tok_start points to the entire "12345_678",
+ while m_ptr points to "678".
+*/
+int Lex_input_stream::scan_ident_start(THD *thd, Lex_ident_cli_st *str)
+{
+ uchar c;
+ bool is_8bit;
+ CHARSET_INFO *const cs= thd->charset();
+ const uchar *const ident_map= cs->ident_map;
+ DBUG_ASSERT(m_tok_start <= m_ptr);
+
+ if (cs->use_mb())
+ {
+ is_8bit= true;
+ while (ident_map[c= yyGet()])
+ {
+ int char_length= cs->charlen(get_ptr() - 1, get_end_of_query());
+ if (char_length <= 0)
+ break;
+ skip_binary(char_length - 1);
+ }
+ }
+ else
+ {
+ is_8bit= get_7bit_or_8bit_ident(thd, &c);
+ }
+ if (c == '.' && ident_map[(uchar) yyPeek()])
+ next_state= MY_LEX_IDENT_SEP;// Next is '.'
+
+ uint length= yyLength();
+ yyUnget(); // ptr points now after last token char
+ str->set_ident(m_tok_start, length, is_8bit);
+ m_cpp_text_start= m_cpp_tok_start;
+ m_cpp_text_end= m_cpp_text_start + length;
+ body_utf8_append(m_cpp_text_start);
+ body_utf8_append_ident(thd, str, m_cpp_text_end);
+ return is_8bit ? IDENT_QUOTED : IDENT;
+}
+
+
+int Lex_input_stream::scan_ident_middle(THD *thd, Lex_ident_cli_st *str,
+ CHARSET_INFO **introducer,
+ my_lex_states *st)
+{
+ CHARSET_INFO *const cs= thd->charset();
+ const uchar *const ident_map= cs->ident_map;
+ const uchar *const state_map= cs->state_map;
+ const char *start;
+ uint length;
+ uchar c;
+ bool is_8bit;
+ bool resolve_introducer= true;
+ DBUG_ASSERT(m_ptr == m_tok_start + 1); // m_ptr points to the second byte
+
+ if (cs->use_mb())
+ {
+ is_8bit= true;
+ int char_length= cs->charlen(get_ptr() - 1, get_end_of_query());
+ if (char_length <= 0)
+ {
+ *st= MY_LEX_CHAR;
+ return 0;
+ }
+ skip_binary(char_length - 1);
+
+ while (ident_map[c= yyGet()])
+ {
+ char_length= cs->charlen(get_ptr() - 1, get_end_of_query());
+ if (char_length <= 0)
+ break;
+ if (char_length > 1 || (c & 0x80))
+ resolve_introducer= false;
+ skip_binary(char_length - 1);
+ }
+ }
+ else
+ {
+ is_8bit= get_7bit_or_8bit_ident(thd, &c) || (m_tok_start[0] & 0x80);
+ resolve_introducer= !is_8bit;
+ }
+ length= yyLength();
+ start= get_ptr();
+ if (ignore_space)
+ {
+ /*
+ If we find a space then this can't be an identifier. We notice this
+ below by checking start != lex->ptr.
+ */
+ for (; state_map[(uchar) c] == MY_LEX_SKIP ; c= yyGet())
+ {
+ if (c == '\n')
+ yylineno++;
+ }
+ }
+ if (start == get_ptr() && c == '.' && ident_map[(uchar) yyPeek()])
+ next_state= MY_LEX_IDENT_SEP;
+ else
+ { // '(' must follow directly if function
+ int tokval;
+ yyUnget();
+ if ((tokval= find_keyword(str, length, c == '(')))
+ {
+ next_state= MY_LEX_START; // Allow signed numbers
+ return(tokval); // Was keyword
+ }
+ yySkip(); // next state does a unget
+ }
+
+ yyUnget(); // ptr points now after last token char
+ str->set_ident(m_tok_start, length, is_8bit);
+ m_cpp_text_start= m_cpp_tok_start;
+ m_cpp_text_end= m_cpp_text_start + length;
+
+ /*
+ Note: "SELECT _bla AS 'alias'"
+ _bla should be considered as a IDENT if charset haven't been found.
+ So we don't use MYF(MY_WME) with get_charset_by_csname to avoid
+ producing an error.
+ */
+ DBUG_ASSERT(length > 0);
+ if (resolve_introducer && m_tok_start[0] == '_')
+ {
+ ErrConvString csname(str->str + 1, str->length - 1, &my_charset_bin);
+ CHARSET_INFO *cs= get_charset_by_csname(csname.ptr(),
+ MY_CS_PRIMARY, MYF(0));
+ if (cs)
+ {
+ body_utf8_append(m_cpp_text_start, m_cpp_tok_start + length);
+ *introducer= cs;
+ return UNDERSCORE_CHARSET;
+ }
+ }
+
+ body_utf8_append(m_cpp_text_start);
+ body_utf8_append_ident(thd, str, m_cpp_text_end);
+ return is_8bit ? IDENT_QUOTED : IDENT;
+}
+
+
+int Lex_input_stream::scan_ident_delimited(THD *thd,
+ Lex_ident_cli_st *str,
+ uchar quote_char)
+{
+ CHARSET_INFO *const cs= thd->charset();
+ uint double_quotes= 0;
+ uchar c;
+ DBUG_ASSERT(m_ptr == m_tok_start + 1);
+
+ for ( ; ; )
+ {
+ if (!(c= yyGet()))
+ {
+ /*
+ End-of-query or straight 0x00 inside a delimited identifier.
+ Return the quote character, to have the parser fail on syntax error.
+ */
+ m_ptr= (char *) m_tok_start + 1;
+ if (m_echo)
+ m_cpp_ptr= (char *) m_cpp_tok_start + 1;
+ return quote_char;
+ }
+ int var_length= cs->charlen(get_ptr() - 1, get_end_of_query());
+ if (var_length == 1)
+ {
+ if (c == quote_char)
+ {
+ if (yyPeek() != quote_char)
+ break;
+ c= yyGet();
+ double_quotes++;
+ continue;
+ }
+ }
+ else if (var_length > 1)
+ {
+ skip_binary(var_length - 1);
+ }
+ }
+
+ str->set_ident_quoted(m_tok_start + 1, yyLength() - 1, true, quote_char);
+ yyUnget(); // ptr points now after last token char
+
+ m_cpp_text_start= m_cpp_tok_start + 1;
+ m_cpp_text_end= m_cpp_text_start + str->length;
+
+ if (c == quote_char)
+ yySkip(); // Skip end `
+ next_state= MY_LEX_START;
+ body_utf8_append(m_cpp_text_start);
+ // QQQ: shouldn't it add unescaped version ????
+ body_utf8_append_ident(thd, str, m_cpp_text_end);
+ return IDENT_QUOTED;
+}
+
+
+void trim_whitespace(CHARSET_INFO *cs, LEX_CSTRING *str, size_t * prefix_length)
+{
+ /*
+ TODO:
+ This code assumes that there are no multi-bytes characters
+ that can be considered white-space.
+ */
+
+ size_t plen= 0;
+ while ((str->length > 0) && (my_isspace(cs, str->str[0])))
+ {
+ plen++;
+ str->length --;
+ str->str ++;
+ }
+ if (prefix_length)
+ *prefix_length= plen;
+ /*
+ FIXME:
+ Also, parsing backward is not safe with multi bytes characters
+ */
+ while ((str->length > 0) && (my_isspace(cs, str->str[str->length-1])))
+ {
+ str->length --;
+ }
+}
+
+
+/*
+ st_select_lex structures initialisations
+*/
+
+void st_select_lex_node::init_query_common()
+{
+ options= 0;
+ set_linkage(UNSPECIFIED_TYPE);
+ distinct= TRUE;
+ no_table_names_allowed= 0;
+ uncacheable= 0;
+}
+
+void st_select_lex_unit::init_query()
+{
+ init_query_common();
+ set_linkage(GLOBAL_OPTIONS_TYPE);
+ lim.set_unlimited();
+ union_distinct= 0;
+ prepared= optimized= optimized_2= executed= 0;
+ bag_set_op_optimized= 0;
+ optimize_started= 0;
+ item= 0;
+ union_result= 0;
+ table= 0;
+ fake_select_lex= 0;
+ saved_fake_select_lex= 0;
+ cleaned= 0;
+ item_list.empty();
+ describe= 0;
+ found_rows_for_union= 0;
+ derived= 0;
+ is_view= false;
+ with_clause= 0;
+ with_element= 0;
+ cloned_from= 0;
+ columns_are_renamed= false;
+ with_wrapped_tvc= false;
+ have_except_all_or_intersect_all= false;
+}
+
+void st_select_lex::init_query()
+{
+ init_query_common();
+ table_list.empty();
+ top_join_list.empty();
+ join_list= &top_join_list;
+ embedding= 0;
+ leaf_tables_prep.empty();
+ leaf_tables.empty();
+ item_list.empty();
+ min_max_opt_list.empty();
+ join= 0;
+ having= prep_having= where= prep_where= 0;
+ cond_pushed_into_where= cond_pushed_into_having= 0;
+ attach_to_conds.empty();
+ olap= UNSPECIFIED_OLAP_TYPE;
+ having_fix_field= 0;
+ having_fix_field_for_pushed_cond= 0;
+ context.select_lex= this;
+ context.init();
+ cond_count= between_count= with_wild= 0;
+ max_equal_elems= 0;
+ ref_pointer_array.reset();
+ select_n_where_fields= 0;
+ select_n_reserved= 0;
+ select_n_having_items= 0;
+ n_sum_items= 0;
+ n_child_sum_items= 0;
+ hidden_bit_fields= 0;
+ fields_in_window_functions= 0;
+ subquery_in_having= explicit_limit= 0;
+ is_item_list_lookup= 0;
+ changed_elements= 0;
+ first_natural_join_processing= 1;
+ first_cond_optimization= 1;
+ is_service_select= 0;
+ parsing_place= NO_MATTER;
+ save_parsing_place= NO_MATTER;
+ context_analysis_place= NO_MATTER;
+ exclude_from_table_unique_test= no_wrap_view_item= FALSE;
+ nest_level= 0;
+ link_next= 0;
+ prep_leaf_list_state= UNINIT;
+ have_merged_subqueries= FALSE;
+ bzero((char*) expr_cache_may_be_used, sizeof(expr_cache_may_be_used));
+ select_list_tables= 0;
+ m_non_agg_field_used= false;
+ m_agg_func_used= false;
+ m_custom_agg_func_used= false;
+ window_specs.empty();
+ window_funcs.empty();
+ tvc= 0;
+ in_tvc= false;
+ versioned_tables= 0;
+ pushdown_select= 0;
+}
+
+void st_select_lex::init_select()
+{
+ sj_nests.empty();
+ sj_subselects.empty();
+ group_list.empty();
+ if (group_list_ptrs)
+ group_list_ptrs->clear();
+ type= 0;
+ db= null_clex_str;
+ having= 0;
+ table_join_options= 0;
+ in_sum_expr= with_wild= 0;
+ options= 0;
+ ftfunc_list_alloc.empty();
+ inner_sum_func_list= 0;
+ ftfunc_list= &ftfunc_list_alloc;
+ order_list.empty();
+ /* Set limit and offset to default values */
+ select_limit= 0; /* denotes the default limit = HA_POS_ERROR */
+ offset_limit= 0; /* denotes the default offset = 0 */
+ is_set_query_expr_tail= false;
+ with_sum_func= 0;
+ with_all_modifier= 0;
+ is_correlated= 0;
+ cur_pos_in_select_list= UNDEF_POS;
+ cond_value= having_value= Item::COND_UNDEF;
+ inner_refs_list.empty();
+ insert_tables= 0;
+ merged_into= 0;
+ m_non_agg_field_used= false;
+ m_agg_func_used= false;
+ m_custom_agg_func_used= false;
+ name_visibility_map.clear_all();
+ with_dep= 0;
+ join= 0;
+ lock_type= TL_READ_DEFAULT;
+ save_many_values.empty();
+ save_insert_list= 0;
+ tvc= 0;
+ in_funcs.empty();
+ curr_tvc_name= 0;
+ in_tvc= false;
+ versioned_tables= 0;
+ nest_flags= 0;
+}
+
+/*
+ st_select_lex structures linking
+*/
+
+/* include on level down */
+void st_select_lex_node::include_down(st_select_lex_node *upper)
+{
+ if ((next= upper->slave))
+ next->prev= &next;
+ prev= &upper->slave;
+ upper->slave= this;
+ master= upper;
+ slave= 0;
+}
+
+
+void st_select_lex_node::add_slave(st_select_lex_node *slave_arg)
+{
+ for (; slave; slave= slave->next)
+ if (slave == slave_arg)
+ return;
+
+ if (slave)
+ {
+ st_select_lex_node *slave_arg_slave= slave_arg->slave;
+ /* Insert in the front of list of slaves if any. */
+ slave_arg->include_neighbour(slave);
+ /* include_neighbour() sets slave_arg->slave=0, restore it. */
+ slave_arg->slave= slave_arg_slave;
+ /* Count on include_neighbour() setting the master. */
+ DBUG_ASSERT(slave_arg->master == this);
+ }
+ else
+ {
+ slave= slave_arg;
+ slave_arg->master= this;
+ slave->prev= &master->slave;
+ slave->next= 0;
+ }
+}
+
+void st_select_lex_node::link_chain_down(st_select_lex_node *first)
+{
+ st_select_lex_node *last_node;
+ st_select_lex_node *node= first;
+ do
+ {
+ last_node= node;
+ node->master= this;
+ node= node->next;
+ } while (node);
+ if ((last_node->next= slave))
+ {
+ slave->prev= &last_node->next;
+ }
+ first->prev= &slave;
+ slave= first;
+}
+
+/*
+ @brief
+ Substitute this node in select tree for a newly creates node
+
+ @param subst the node to substitute for
+
+ @details
+ The function substitute this node in the select tree for a newly
+ created node subst. This node is just removed from the tree but all
+ its link fields and the attached sub-tree remain untouched.
+*/
+
+void st_select_lex_node::substitute_in_tree(st_select_lex_node *subst)
+{
+ if ((subst->next= next))
+ next->prev= &subst->next;
+ subst->prev= prev;
+ (*prev)= subst;
+ subst->master= master;
+}
+
+/*
+ include on level down (but do not link)
+
+ SYNOPSYS
+ st_select_lex_node::include_standalone()
+ upper - reference on node underr which this node should be included
+ ref - references on reference on this node
+*/
+void st_select_lex_node::include_standalone(st_select_lex_node *upper,
+ st_select_lex_node **ref)
+{
+ next= 0;
+ prev= ref;
+ master= upper;
+ slave= 0;
+}
+
+/* include neighbour (on same level) */
+void st_select_lex_node::include_neighbour(st_select_lex_node *before)
+{
+ if ((next= before->next))
+ next->prev= &next;
+ prev= &before->next;
+ before->next= this;
+ master= before->master;
+ slave= 0;
+}
+
+/* including in global SELECT_LEX list */
+void st_select_lex_node::include_global(st_select_lex_node **plink)
+{
+ if ((link_next= *plink))
+ link_next->link_prev= &link_next;
+ link_prev= plink;
+ *plink= this;
+}
+
+//excluding from global list (internal function)
+void st_select_lex_node::fast_exclude()
+{
+ if (link_prev)
+ {
+ if ((*link_prev= link_next))
+ link_next->link_prev= link_prev;
+ }
+ // Remove slave structure
+ for (; slave; slave= slave->next)
+ slave->fast_exclude();
+
+}
+
+
+/**
+ @brief
+ Insert a new chain of nodes into another chain before a particular link
+
+ @param in/out
+ ptr_pos_to_insert the address of the chain pointer pointing to the link
+ before which the subchain has to be inserted
+ @param
+ end_chain_node the last link of the subchain to be inserted
+
+ @details
+ The method inserts the chain of nodes starting from this node and ending
+ with the node nd_chain_node into another chain of nodes before the node
+ pointed to by *ptr_pos_to_insert.
+ It is assumed that ptr_pos_to_insert belongs to the chain where we insert.
+ So it must be updated.
+
+ @retval
+ The method returns the pointer to the first link of the inserted chain
+*/
+
+st_select_lex_node *st_select_lex_node:: insert_chain_before(
+ st_select_lex_node **ptr_pos_to_insert,
+ st_select_lex_node *end_chain_node)
+{
+ end_chain_node->link_next= *ptr_pos_to_insert;
+ (*ptr_pos_to_insert)->link_prev= &end_chain_node->link_next;
+ link_prev= ptr_pos_to_insert;
+ return this;
+}
+
+
+/*
+ Detach the node from its master and attach it to a new master
+*/
+
+void st_select_lex_node::move_as_slave(st_select_lex_node *new_master)
+{
+ exclude_from_tree();
+ if (new_master->slave)
+ {
+ st_select_lex_node *curr= new_master->slave;
+ for ( ; curr->next ; curr= curr->next) ;
+ prev= &curr->next;
+ }
+ else
+ prev= &new_master->slave;
+ *prev= this;
+ next= 0;
+ master= new_master;
+}
+
+
+/*
+ Exclude a node from the tree lex structure, but leave it in the global
+ list of nodes.
+*/
+
+void st_select_lex_node::exclude_from_tree()
+{
+ if ((*prev= next))
+ next->prev= prev;
+}
+
+
+/*
+ Exclude select_lex structure (except first (first select can't be
+ deleted, because it is most upper select))
+*/
+void st_select_lex_node::exclude()
+{
+ /* exclude from global list */
+ fast_exclude();
+ /* exclude from other structures */
+ exclude_from_tree();
+ /*
+ We do not need following statements, because prev pointer of first
+ list element point to master->slave
+ if (master->slave == this)
+ master->slave= next;
+ */
+}
+
+
+/*
+ Exclude level of current unit from tree of SELECTs
+
+ SYNOPSYS
+ st_select_lex_unit::exclude_level()
+
+ NOTE: units which belong to current will be brought up on level of
+ currernt unit
+*/
+void st_select_lex_unit::exclude_level()
+{
+ SELECT_LEX_UNIT *units= 0, **units_last= &units;
+ for (SELECT_LEX *sl= first_select(); sl; sl= sl->next_select())
+ {
+ // unlink current level from global SELECTs list
+ if (sl->link_prev && (*sl->link_prev= sl->link_next))
+ sl->link_next->link_prev= sl->link_prev;
+
+ // bring up underlay levels
+ SELECT_LEX_UNIT **last= 0;
+ for (SELECT_LEX_UNIT *u= sl->first_inner_unit(); u; u= u->next_unit())
+ {
+ u->master= master;
+ last= (SELECT_LEX_UNIT**)&(u->next);
+ }
+ if (last)
+ {
+ (*units_last)= sl->first_inner_unit();
+ units_last= last;
+ }
+ }
+ if (units)
+ {
+ // include brought up levels in place of current
+ (*prev)= units;
+ (*units_last)= (SELECT_LEX_UNIT*)next;
+ if (next)
+ next->prev= (SELECT_LEX_NODE**)units_last;
+ units->prev= prev;
+ }
+ else
+ {
+ // exclude currect unit from list of nodes
+ (*prev)= next;
+ if (next)
+ next->prev= prev;
+ }
+ // Mark it excluded
+ prev= NULL;
+}
+
+
+#if 0
+/*
+ Exclude subtree of current unit from tree of SELECTs
+
+ SYNOPSYS
+ st_select_lex_unit::exclude_tree()
+*/
+void st_select_lex_unit::exclude_tree()
+{
+ for (SELECT_LEX *sl= first_select(); sl; sl= sl->next_select())
+ {
+ // unlink current level from global SELECTs list
+ if (sl->link_prev && (*sl->link_prev= sl->link_next))
+ sl->link_next->link_prev= sl->link_prev;
+
+ // unlink underlay levels
+ for (SELECT_LEX_UNIT *u= sl->first_inner_unit(); u; u= u->next_unit())
+ {
+ u->exclude_level();
+ }
+ }
+ // exclude currect unit from list of nodes
+ (*prev)= next;
+ if (next)
+ next->prev= prev;
+}
+#endif
+
+
+/*
+ st_select_lex_node::mark_as_dependent mark all st_select_lex struct from
+ this to 'last' as dependent
+
+ SYNOPSIS
+ last - pointer to last st_select_lex struct, before which all
+ st_select_lex have to be marked as dependent
+
+ NOTE
+ 'last' should be reachable from this st_select_lex_node
+*/
+
+bool st_select_lex::mark_as_dependent(THD *thd, st_select_lex *last,
+ Item_ident *dependency)
+{
+
+ DBUG_ASSERT(this != last);
+
+ /*
+ Mark all selects from resolved to 1 before select where was
+ found table as depended (of select where was found table)
+
+ We move by name resolution context, bacause during merge can some select
+ be excleded from SELECT tree
+ */
+ Name_resolution_context *c= &this->context;
+ do
+ {
+ SELECT_LEX *s= c->select_lex;
+ if (!(s->uncacheable & UNCACHEABLE_DEPENDENT_GENERATED))
+ {
+ // Select is dependent of outer select
+ s->uncacheable= (s->uncacheable & ~UNCACHEABLE_UNITED) |
+ UNCACHEABLE_DEPENDENT_GENERATED;
+ SELECT_LEX_UNIT *munit= s->master_unit();
+ munit->uncacheable= (munit->uncacheable & ~UNCACHEABLE_UNITED) |
+ UNCACHEABLE_DEPENDENT_GENERATED;
+ for (SELECT_LEX *sl= munit->first_select(); sl ; sl= sl->next_select())
+ {
+ if (sl != s &&
+ !(sl->uncacheable & (UNCACHEABLE_DEPENDENT_GENERATED |
+ UNCACHEABLE_UNITED)))
+ sl->uncacheable|= UNCACHEABLE_UNITED;
+ }
+ }
+
+ Item_subselect *subquery_expr= s->master_unit()->item;
+ if (subquery_expr && subquery_expr->mark_as_dependent(thd, last,
+ dependency))
+ return TRUE;
+ } while ((c= c->outer_context) != NULL && (c->select_lex != last));
+ is_correlated= TRUE;
+ master_unit()->item->is_correlated= TRUE;
+ return FALSE;
+}
+
+/*
+ prohibit using LIMIT clause
+*/
+bool st_select_lex::test_limit()
+{
+ if (select_limit != 0)
+ {
+ my_error(ER_NOT_SUPPORTED_YET, MYF(0),
+ "LIMIT & IN/ALL/ANY/SOME subquery");
+ return(1);
+ }
+ return(0);
+}
+
+
+
+st_select_lex* st_select_lex_unit::outer_select()
+{
+ return (st_select_lex*) master;
+}
+
+
+ha_rows st_select_lex::get_offset()
+{
+ ulonglong val= 0;
+
+ if (offset_limit)
+ {
+ // see comment for st_select_lex::get_limit()
+ bool err= offset_limit->fix_fields_if_needed(master_unit()->thd, NULL);
+ DBUG_ASSERT(!err);
+ val= err ? HA_POS_ERROR : offset_limit->val_uint();
+ }
+
+ return (ha_rows)val;
+}
+
+
+ha_rows st_select_lex::get_limit()
+{
+ ulonglong val= HA_POS_ERROR;
+
+ if (select_limit)
+ {
+ /*
+ fix_fields() has not been called for select_limit. That's due to the
+ historical reasons -- this item could be only of type Item_int, and
+ Item_int does not require fix_fields(). Thus, fix_fields() was never
+ called for select_limit.
+
+ Some time ago, Item_splocal was also allowed for LIMIT / OFFSET clauses.
+ However, the fix_fields() behavior was not updated, which led to a crash
+ in some cases.
+
+ There is no single place where to call fix_fields() for LIMIT / OFFSET
+ items during the fix-fields-phase. Thus, for the sake of readability,
+ it was decided to do it here, on the evaluation phase (which is a
+ violation of design, but we chose the lesser of two evils).
+
+ We can call fix_fields() here, because select_limit can be of two
+ types only: Item_int and Item_splocal. Item_int::fix_fields() is trivial,
+ and Item_splocal::fix_fields() (or rather Item_sp_variable::fix_fields())
+ has the following properties:
+ 1) it does not affect other items;
+ 2) it does not fail.
+
+ Nevertheless DBUG_ASSERT was added to catch future changes in
+ fix_fields() implementation. Also added runtime check against a result
+ of fix_fields() in order to handle error condition in non-debug build.
+ */
+ bool err= select_limit->fix_fields_if_needed(master_unit()->thd, NULL);
+ DBUG_ASSERT(!err);
+ val= err ? HA_POS_ERROR : select_limit->val_uint();
+ }
+
+ return (ha_rows)val;
+}
+
+
+bool st_select_lex::add_order_to_list(THD *thd, Item *item, bool asc)
+{
+ return add_to_list(thd, order_list, item, asc);
+}
+
+
+bool st_select_lex::add_gorder_to_list(THD *thd, Item *item, bool asc)
+{
+ return add_to_list(thd, gorder_list, item, asc);
+}
+
+
+bool st_select_lex::add_item_to_list(THD *thd, Item *item)
+{
+ DBUG_ENTER("st_select_lex::add_item_to_list");
+ DBUG_PRINT("info", ("Item: %p", item));
+ DBUG_RETURN(item_list.push_back(item, thd->mem_root));
+}
+
+
+bool st_select_lex::add_group_to_list(THD *thd, Item *item, bool asc)
+{
+ return add_to_list(thd, group_list, item, asc);
+}
+
+
+bool st_select_lex::add_ftfunc_to_list(THD *thd, Item_func_match *func)
+{
+ return !func || ftfunc_list->push_back(func, thd->mem_root); // end of memory?
+}
+
+
+st_select_lex* st_select_lex::outer_select()
+{
+ return (st_select_lex*) master->get_master();
+}
+
+
+bool st_select_lex::inc_in_sum_expr()
+{
+ in_sum_expr++;
+ return 0;
+}
+
+
+uint st_select_lex::get_in_sum_expr()
+{
+ return in_sum_expr;
+}
+
+
+TABLE_LIST* st_select_lex::get_table_list()
+{
+ return table_list.first;
+}
+
+List<Item>* st_select_lex::get_item_list()
+{
+ return &item_list;
+}
+
+ulong st_select_lex::get_table_join_options()
+{
+ return table_join_options;
+}
+
+
+bool st_select_lex::setup_ref_array(THD *thd, uint order_group_num)
+{
+
+ if (!((options & SELECT_DISTINCT) && !group_list.elements))
+ hidden_bit_fields= 0;
+
+ // find_order_in_list() may need some extra space, so multiply by two.
+ order_group_num*= 2;
+
+ /*
+ We have to create array in prepared statement memory if it is a
+ prepared statement
+ */
+ Query_arena *arena= thd->stmt_arena;
+ const uint n_elems= (n_sum_items +
+ n_child_sum_items +
+ item_list.elements +
+ select_n_reserved +
+ select_n_having_items +
+ select_n_where_fields +
+ order_group_num +
+ hidden_bit_fields +
+ fields_in_window_functions) * 5;
+ if (!ref_pointer_array.is_null())
+ {
+ /*
+ We need to take 'n_sum_items' into account when allocating the array,
+ and this may actually increase during the optimization phase due to
+ MIN/MAX rewrite in Item_in_subselect::single_value_transformer.
+ In the usual case we can reuse the array from the prepare phase.
+ If we need a bigger array, we must allocate a new one.
+ */
+ if (ref_pointer_array.size() >= n_elems)
+ return false;
+ }
+ Item **array= static_cast<Item**>(arena->alloc(sizeof(Item*) * n_elems));
+ if (likely(array != NULL))
+ ref_pointer_array= Ref_ptr_array(array, n_elems);
+
+ return array == NULL;
+}
+
+
+/*
+ @brief
+ Print the whole statement
+
+ @param str Print into this string
+ @param query_type Flags describing how to print
+
+ @detail
+ The intent is to allow to eventually print back any query.
+
+ This is useful e.g. for storage engines that take over diferrent kinds of
+ queries
+*/
+
+void LEX::print(String *str, enum_query_type query_type)
+{
+ if (sql_command == SQLCOM_UPDATE)
+ {
+ SELECT_LEX *sel= first_select_lex();
+ str->append(STRING_WITH_LEN("UPDATE "));
+ if (ignore)
+ str->append(STRING_WITH_LEN("IGNORE "));
+ // table name. If the query was using a view, we need
+ // the underlying table name, not the view name
+ TABLE_LIST *base_tbl= query_tables->table->pos_in_table_list;
+ base_tbl->print(thd, table_map(0), str, query_type);
+ str->append(STRING_WITH_LEN(" SET "));
+ // print item assignments
+ List_iterator<Item> it(sel->item_list);
+ List_iterator<Item> it2(value_list);
+ Item *col_ref, *value;
+ bool first= true;
+ while ((col_ref= it++) && (value= it2++))
+ {
+ if (first)
+ first= false;
+ else
+ str->append(STRING_WITH_LEN(", "));
+ col_ref->print(str, query_type);
+ str->append(STRING_WITH_LEN("="));
+ value->print(str, query_type);
+ }
+
+ if (sel->where)
+ {
+ str->append(STRING_WITH_LEN(" WHERE "));
+ sel->where->print(str, query_type);
+ }
+
+ if (sel->order_list.elements)
+ {
+ str->append(STRING_WITH_LEN(" ORDER BY "));
+ for (ORDER *ord= sel->order_list.first; ord; ord= ord->next)
+ {
+ if (ord != sel->order_list.first)
+ str->append(STRING_WITH_LEN(", "));
+ (*ord->item)->print(str, query_type);
+ }
+ }
+ if (sel->select_limit)
+ {
+ str->append(STRING_WITH_LEN(" LIMIT "));
+ sel->select_limit->print(str, query_type);
+ }
+ }
+ else if (sql_command == SQLCOM_DELETE)
+ {
+ SELECT_LEX *sel= first_select_lex();
+ str->append(STRING_WITH_LEN("DELETE "));
+ if (ignore)
+ str->append(STRING_WITH_LEN("IGNORE "));
+
+ str->append(STRING_WITH_LEN("FROM "));
+ // table name. If the query was using a view, we need
+ // the underlying table name, not the view name
+ TABLE_LIST *base_tbl= query_tables->table->pos_in_table_list;
+ base_tbl->print(thd, table_map(0), str, query_type);
+
+ if (sel->where)
+ {
+ str->append(STRING_WITH_LEN(" WHERE "));
+ sel->where->print(str, query_type);
+ }
+
+ if (sel->order_list.elements)
+ {
+ str->append(STRING_WITH_LEN(" ORDER BY "));
+ for (ORDER *ord= sel->order_list.first; ord; ord= ord->next)
+ {
+ if (ord != sel->order_list.first)
+ str->append(STRING_WITH_LEN(", "));
+ (*ord->item)->print(str, query_type);
+ }
+ }
+ if (sel->select_limit)
+ {
+ str->append(STRING_WITH_LEN(" LIMIT "));
+ sel->select_limit->print(str, query_type);
+ }
+ }
+ else
+ DBUG_ASSERT(0); // Not implemented yet
+}
+
+void st_select_lex_unit::print(String *str, enum_query_type query_type)
+{
+ if (with_clause)
+ with_clause->print(thd, str, query_type);
+ for (SELECT_LEX *sl= first_select(); sl; sl= sl->next_select())
+ {
+ if (sl != first_select())
+ {
+ switch (sl->linkage)
+ {
+ default:
+ DBUG_ASSERT(0);
+ /* fall through */
+ case UNION_TYPE:
+ str->append(STRING_WITH_LEN(" union "));
+ break;
+ case INTERSECT_TYPE:
+ str->append(STRING_WITH_LEN(" intersect "));
+ break;
+ case EXCEPT_TYPE:
+ str->append(STRING_WITH_LEN(" except "));
+ break;
+ }
+ if (!sl->distinct)
+ str->append(STRING_WITH_LEN("all "));
+ }
+ if (sl->braces)
+ str->append('(');
+ sl->print(thd, str, query_type);
+ if (sl->braces)
+ str->append(')');
+ }
+ if (fake_select_lex)
+ {
+ if (fake_select_lex->order_list.elements)
+ {
+ str->append(STRING_WITH_LEN(" order by "));
+ fake_select_lex->print_order(str,
+ fake_select_lex->order_list.first,
+ query_type);
+ }
+ fake_select_lex->print_limit(thd, str, query_type);
+ }
+ else if (saved_fake_select_lex)
+ saved_fake_select_lex->print_limit(thd, str, query_type);
+}
+
+
+void st_select_lex::print_order(String *str,
+ ORDER *order,
+ enum_query_type query_type)
+{
+ for (; order; order= order->next)
+ {
+ if (order->counter_used)
+ {
+ char buffer[20];
+ size_t length= my_snprintf(buffer, 20, "%d", order->counter);
+ str->append(buffer, (uint) length);
+ }
+ else
+ {
+ /* replace numeric reference with equivalent for ORDER constant */
+ if (order->item[0]->is_order_clause_position())
+ {
+ /* make it expression instead of integer constant */
+ str->append(STRING_WITH_LEN("''"));
+ }
+ else
+ (*order->item)->print(str, query_type);
+ }
+ if (order->direction == ORDER::ORDER_DESC)
+ str->append(STRING_WITH_LEN(" desc"));
+ if (order->next)
+ str->append(',');
+ }
+}
+
+
+void st_select_lex::print_limit(THD *thd,
+ String *str,
+ enum_query_type query_type)
+{
+ SELECT_LEX_UNIT *unit= master_unit();
+ Item_subselect *item= unit->item;
+
+ if (item && unit->global_parameters() == this)
+ {
+ Item_subselect::subs_type subs_type= item->substype();
+ if (subs_type == Item_subselect::IN_SUBS ||
+ subs_type == Item_subselect::ALL_SUBS)
+ {
+ return;
+ }
+ }
+ if (explicit_limit && select_limit)
+ {
+ str->append(STRING_WITH_LEN(" limit "));
+ if (offset_limit)
+ {
+ offset_limit->print(str, query_type);
+ str->append(',');
+ }
+ select_limit->print(str, query_type);
+ }
+}
+
+
+/**
+ @brief Restore the LEX and THD in case of a parse error.
+
+ This is a clean up call that is invoked by the Bison generated
+ parser before returning an error from MYSQLparse. If your
+ semantic actions manipulate with the global thread state (which
+ is a very bad practice and should not normally be employed) and
+ need a clean-up in case of error, and you can not use %destructor
+ rule in the grammar file itself, this function should be used
+ to implement the clean up.
+*/
+
+void LEX::cleanup_lex_after_parse_error(THD *thd)
+{
+ /*
+ Delete sphead for the side effect of restoring of the original
+ LEX state, thd->lex, thd->mem_root and thd->free_list if they
+ were replaced when parsing stored procedure statements. We
+ will never use sphead object after a parse error, so it's okay
+ to delete it only for the sake of the side effect.
+ TODO: make this functionality explicit in sp_head class.
+ Sic: we must nullify the member of the main lex, not the
+ current one that will be thrown away
+ */
+ if (thd->lex->sphead)
+ {
+ sp_package *pkg;
+ thd->lex->sphead->restore_thd_mem_root(thd);
+ if ((pkg= thd->lex->sphead->m_parent))
+ {
+ /*
+ If a syntax error happened inside a package routine definition,
+ then thd->lex points to the routine sublex. We need to restore to
+ the top level LEX.
+ */
+ DBUG_ASSERT(pkg->m_top_level_lex);
+ DBUG_ASSERT(pkg == pkg->m_top_level_lex->sphead);
+ pkg->restore_thd_mem_root(thd);
+ LEX *top= pkg->m_top_level_lex;
+ sp_package::destroy(pkg);
+ thd->lex= top;
+ thd->lex->sphead= NULL;
+ }
+ else
+ {
+ sp_head::destroy(thd->lex->sphead);
+ thd->lex->sphead= NULL;
+ }
+ }
+}
+
+/*
+ Initialize (or reset) Query_tables_list object.
+
+ SYNOPSIS
+ reset_query_tables_list()
+ init TRUE - we should perform full initialization of object with
+ allocating needed memory
+ FALSE - object is already initialized so we should only reset
+ its state so it can be used for parsing/processing
+ of new statement
+
+ DESCRIPTION
+ This method initializes Query_tables_list so it can be used as part
+ of LEX object for parsing/processing of statement. One can also use
+ this method to reset state of already initialized Query_tables_list
+ so it can be used for processing of new statement.
+*/
+
+void Query_tables_list::reset_query_tables_list(bool init)
+{
+ sql_command= SQLCOM_END;
+ if (!init && query_tables)
+ {
+ TABLE_LIST *table= query_tables;
+ for (;;)
+ {
+ delete table->view;
+ if (query_tables_last == &table->next_global ||
+ !(table= table->next_global))
+ break;
+ }
+ }
+ query_tables= 0;
+ query_tables_last= &query_tables;
+ query_tables_own_last= 0;
+ if (init)
+ {
+ /*
+ We delay real initialization of hash (and therefore related
+ memory allocation) until first insertion into this hash.
+ */
+ my_hash_clear(&sroutines);
+ }
+ else if (sroutines.records)
+ {
+ /* Non-zero sroutines.records means that hash was initialized. */
+ my_hash_reset(&sroutines);
+ }
+ sroutines_list.empty();
+ sroutines_list_own_last= sroutines_list.next;
+ sroutines_list_own_elements= 0;
+ binlog_stmt_flags= 0;
+ stmt_accessed_table_flag= 0;
+}
+
+
+/*
+ Destroy Query_tables_list object with freeing all resources used by it.
+
+ SYNOPSIS
+ destroy_query_tables_list()
+*/
+
+void Query_tables_list::destroy_query_tables_list()
+{
+ my_hash_free(&sroutines);
+}
+
+
+/*
+ Initialize LEX object.
+
+ SYNOPSIS
+ LEX::LEX()
+
+ NOTE
+ LEX object initialized with this constructor can be used as part of
+ THD object for which one can safely call open_tables(), lock_tables()
+ and close_thread_tables() functions. But it is not yet ready for
+ statement parsing. On should use lex_start() function to prepare LEX
+ for this.
+*/
+
+LEX::LEX()
+ : explain(NULL), result(0), part_info(NULL), arena_for_set_stmt(0), mem_root_for_set_stmt(0),
+ option_type(OPT_DEFAULT), context_analysis_only(0), sphead(0),
+ default_used(0), is_lex_started(0), limit_rows_examined_cnt(ULONGLONG_MAX)
+{
+
+ init_dynamic_array2(PSI_INSTRUMENT_ME, &plugins, sizeof(plugin_ref),
+ plugins_static_buffer, INITIAL_LEX_PLUGIN_LIST_SIZE,
+ INITIAL_LEX_PLUGIN_LIST_SIZE, 0);
+ reset_query_tables_list(TRUE);
+ mi.init();
+ init_dynamic_array2(PSI_INSTRUMENT_ME, &delete_gtid_domain, sizeof(uint32),
+ gtid_domain_static_buffer,
+ initial_gtid_domain_buffer_size,
+ initial_gtid_domain_buffer_size, 0);
+ unit.slave= &builtin_select;
+}
+
+
+/*
+ Check whether the merging algorithm can be used on this VIEW
+
+ SYNOPSIS
+ LEX::can_be_merged()
+
+ DESCRIPTION
+ We can apply merge algorithm if it is single SELECT view with
+ subqueries only in WHERE clause (we do not count SELECTs of underlying
+ views, and second level subqueries) and we have not grpouping, ordering,
+ HAVING clause, aggregate functions, DISTINCT clause, LIMIT clause and
+ several underlying tables.
+
+ RETURN
+ FALSE - only temporary table algorithm can be used
+ TRUE - merge algorithm can be used
+*/
+
+bool LEX::can_be_merged()
+{
+ // TODO: do not forget implement case when select_lex.table_list.elements==0
+
+ /* find non VIEW subqueries/unions */
+ bool selects_allow_merge= (first_select_lex()->next_select() == 0 &&
+ !(first_select_lex()->uncacheable &
+ UNCACHEABLE_RAND));
+ if (selects_allow_merge)
+ {
+ for (SELECT_LEX_UNIT *tmp_unit= first_select_lex()->first_inner_unit();
+ tmp_unit;
+ tmp_unit= tmp_unit->next_unit())
+ {
+ if (tmp_unit->first_select()->parent_lex == this &&
+ (tmp_unit->item != 0 &&
+ (tmp_unit->item->place() != IN_WHERE &&
+ tmp_unit->item->place() != IN_ON &&
+ tmp_unit->item->place() != SELECT_LIST)))
+ {
+ selects_allow_merge= 0;
+ break;
+ }
+ }
+ }
+
+ return (selects_allow_merge &&
+ first_select_lex()->group_list.elements == 0 &&
+ first_select_lex()->having == 0 &&
+ first_select_lex()->with_sum_func == 0 &&
+ first_select_lex()->table_list.elements >= 1 &&
+ !(first_select_lex()->options & SELECT_DISTINCT) &&
+ first_select_lex()->select_limit == 0);
+}
+
+
+/*
+ check if command can use VIEW with MERGE algorithm (for top VIEWs)
+
+ SYNOPSIS
+ LEX::can_use_merged()
+
+ DESCRIPTION
+ Only listed here commands can use merge algorithm in top level
+ SELECT_LEX (for subqueries will be used merge algorithm if
+ LEX::can_not_use_merged() is not TRUE).
+
+ RETURN
+ FALSE - command can't use merged VIEWs
+ TRUE - VIEWs with MERGE algorithms can be used
+*/
+
+bool LEX::can_use_merged()
+{
+ switch (sql_command)
+ {
+ case SQLCOM_SELECT:
+ case SQLCOM_CREATE_TABLE:
+ case SQLCOM_UPDATE:
+ case SQLCOM_UPDATE_MULTI:
+ case SQLCOM_DELETE:
+ case SQLCOM_DELETE_MULTI:
+ case SQLCOM_INSERT:
+ case SQLCOM_INSERT_SELECT:
+ case SQLCOM_REPLACE:
+ case SQLCOM_REPLACE_SELECT:
+ case SQLCOM_LOAD:
+ return TRUE;
+ default:
+ return FALSE;
+ }
+}
+
+/*
+ Check if command can't use merged views in any part of command
+
+ SYNOPSIS
+ LEX::can_not_use_merged()
+
+ DESCRIPTION
+ Temporary table algorithm will be used on all SELECT levels for queries
+ listed here (see also LEX::can_use_merged()).
+
+ RETURN
+ FALSE - command can't use merged VIEWs
+ TRUE - VIEWs with MERGE algorithms can be used
+*/
+
+bool LEX::can_not_use_merged()
+{
+ switch (sql_command)
+ {
+ case SQLCOM_CREATE_VIEW:
+ case SQLCOM_SHOW_CREATE:
+ /*
+ SQLCOM_SHOW_FIELDS is necessary to make
+ information schema tables working correctly with views.
+ see get_schema_tables_result function
+ */
+ case SQLCOM_SHOW_FIELDS:
+ return TRUE;
+ default:
+ return FALSE;
+ }
+}
+
+/**
+ Detect that we need only table structure of derived table/view.
+
+ Also used by I_S tables (@see create_schema_table) to detect that
+ they need a full table structure and cannot optimize unused columns away
+
+ @retval TRUE yes, we need only structure
+ @retval FALSE no, we need data
+*/
+
+bool LEX::only_view_structure()
+{
+ switch (sql_command) {
+ case SQLCOM_SHOW_CREATE:
+ case SQLCOM_CHECKSUM:
+ case SQLCOM_SHOW_TABLES:
+ case SQLCOM_SHOW_FIELDS:
+ case SQLCOM_REVOKE_ALL:
+ case SQLCOM_REVOKE:
+ case SQLCOM_GRANT:
+ case SQLCOM_CREATE_VIEW:
+ return TRUE;
+ case SQLCOM_CREATE_TABLE:
+ return create_info.like();
+ default:
+ return FALSE;
+ }
+}
+
+
+/*
+ Should Items_ident be printed correctly
+
+ SYNOPSIS
+ need_correct_ident()
+
+ RETURN
+ TRUE yes, we need only structure
+ FALSE no, we need data
+*/
+
+
+bool LEX::need_correct_ident()
+{
+ switch(sql_command)
+ {
+ case SQLCOM_SHOW_CREATE:
+ case SQLCOM_SHOW_TABLES:
+ case SQLCOM_CREATE_VIEW:
+ return TRUE;
+ default:
+ return FALSE;
+ }
+}
+
+/*
+ Get effective type of CHECK OPTION for given view
+
+ SYNOPSIS
+ get_effective_with_check()
+ view given view
+
+ NOTE
+ It have not sense to set CHECK OPTION for SELECT satement or subqueries,
+ so we do not.
+
+ RETURN
+ VIEW_CHECK_NONE no need CHECK OPTION
+ VIEW_CHECK_LOCAL CHECK OPTION LOCAL
+ VIEW_CHECK_CASCADED CHECK OPTION CASCADED
+*/
+
+uint8 LEX::get_effective_with_check(TABLE_LIST *view)
+{
+ if (view->select_lex->master_unit() == &unit &&
+ which_check_option_applicable())
+ return (uint8)view->with_check;
+ return VIEW_CHECK_NONE;
+}
+
+
+/**
+ This method should be called only during parsing.
+ It is aware of compound statements (stored routine bodies)
+ and will initialize the destination with the default
+ database of the stored routine, rather than the default
+ database of the connection it is parsed in.
+ E.g. if one has no current database selected, or current database
+ set to 'bar' and then issues:
+
+ CREATE PROCEDURE foo.p1() BEGIN SELECT * FROM t1 END//
+
+ t1 is meant to refer to foo.t1, not to bar.t1.
+
+ This method is needed to support this rule.
+
+ @return TRUE in case of error (parsing should be aborted, FALSE in
+ case of success
+*/
+
+bool LEX::copy_db_to(LEX_CSTRING *to)
+{
+ if (sphead && sphead->m_name.str)
+ {
+ DBUG_ASSERT(sphead->m_db.str && sphead->m_db.length);
+ /*
+ It is safe to assign the string by-pointer, both sphead and
+ its statements reside in the same memory root.
+ */
+ *to= sphead->m_db;
+ return FALSE;
+ }
+ return thd->copy_db_to(to);
+}
+
+/**
+ Initialize offset and limit counters.
+
+ @param sl SELECT_LEX to get offset and limit from.
+*/
+
+void st_select_lex_unit::set_limit(st_select_lex *sl)
+{
+ DBUG_ASSERT(!thd->stmt_arena->is_stmt_prepare());
+
+ lim.set_limit(sl->get_limit(), sl->get_offset());
+}
+
+
+/**
+ Decide if a temporary table is needed for the UNION.
+
+ @retval true A temporary table is needed.
+ @retval false A temporary table is not needed.
+ */
+
+bool st_select_lex_unit::union_needs_tmp_table()
+{
+ if (with_element && with_element->is_recursive)
+ return true;
+ if (!with_wrapped_tvc)
+ {
+ for (st_select_lex *sl= first_select(); sl; sl=sl->next_select())
+ {
+ if (sl->tvc && sl->tvc->to_be_wrapped_as_with_tail())
+ {
+ with_wrapped_tvc= true;
+ break;
+ }
+ if (sl != first_select() && sl->linkage != UNION_TYPE)
+ return true;
+ }
+ }
+ if (with_wrapped_tvc)
+ return true;
+ return union_distinct != NULL ||
+ global_parameters()->order_list.elements != 0 ||
+ thd->lex->sql_command == SQLCOM_INSERT_SELECT ||
+ thd->lex->sql_command == SQLCOM_REPLACE_SELECT;
+}
+
+/**
+ @brief Set the initial purpose of this TABLE_LIST object in the list of used
+ tables.
+
+ We need to track this information on table-by-table basis, since when this
+ table becomes an element of the pre-locked list, it's impossible to identify
+ which SQL sub-statement it has been originally used in.
+
+ E.g.:
+
+ User request: SELECT * FROM t1 WHERE f1();
+ FUNCTION f1(): DELETE FROM t2; RETURN 1;
+ BEFORE DELETE trigger on t2: INSERT INTO t3 VALUES (old.a);
+
+ For this user request, the pre-locked list will contain t1, t2, t3
+ table elements, each needed for different DML.
+
+ The trigger event map is updated to reflect INSERT, UPDATE, DELETE,
+ REPLACE, LOAD DATA, CREATE TABLE .. SELECT, CREATE TABLE ..
+ REPLACE SELECT statements, and additionally ON DUPLICATE KEY UPDATE
+ clause.
+*/
+
+void LEX::set_trg_event_type_for_tables()
+{
+ uint8 new_trg_event_map= 0;
+ DBUG_ENTER("LEX::set_trg_event_type_for_tables");
+
+ /*
+ Some auxiliary operations
+ (e.g. GRANT processing) create TABLE_LIST instances outside
+ the parser. Additionally, some commands (e.g. OPTIMIZE) change
+ the lock type for a table only after parsing is done. Luckily,
+ these do not fire triggers and do not need to pre-load them.
+ For these TABLE_LISTs set_trg_event_type is never called, and
+ trg_event_map is always empty. That means that the pre-locking
+ algorithm will ignore triggers defined on these tables, if
+ any, and the execution will either fail with an assert in
+ sql_trigger.cc or with an error that a used table was not
+ pre-locked, in case of a production build.
+
+ TODO: this usage pattern creates unnecessary module dependencies
+ and should be rewritten to go through the parser.
+ Table list instances created outside the parser in most cases
+ refer to mysql.* system tables. It is not allowed to have
+ a trigger on a system table, but keeping track of
+ initialization provides extra safety in case this limitation
+ is circumvented.
+ */
+
+ switch (sql_command) {
+ case SQLCOM_LOCK_TABLES:
+ /*
+ On a LOCK TABLE, all triggers must be pre-loaded for this TABLE_LIST
+ when opening an associated TABLE.
+ */
+ new_trg_event_map= trg2bit(TRG_EVENT_INSERT) | trg2bit(TRG_EVENT_UPDATE) |
+ trg2bit(TRG_EVENT_DELETE);
+ break;
+ /*
+ Basic INSERT. If there is an additional ON DUPLIATE KEY UPDATE
+ clause, it will be handled later in this method.
+ */
+ case SQLCOM_INSERT: /* fall through */
+ case SQLCOM_INSERT_SELECT:
+ /*
+ LOAD DATA ... INFILE is expected to fire BEFORE/AFTER INSERT
+ triggers.
+ If the statement also has REPLACE clause, it will be
+ handled later in this method.
+ */
+ case SQLCOM_LOAD: /* fall through */
+ /*
+ REPLACE is semantically equivalent to INSERT. In case
+ of a primary or unique key conflict, it deletes the old
+ record and inserts a new one. So we also may need to
+ fire ON DELETE triggers. This functionality is handled
+ later in this method.
+ */
+ case SQLCOM_REPLACE: /* fall through */
+ case SQLCOM_REPLACE_SELECT:
+ /*
+ CREATE TABLE ... SELECT defaults to INSERT if the table or
+ view already exists. REPLACE option of CREATE TABLE ...
+ REPLACE SELECT is handled later in this method.
+ */
+ case SQLCOM_CREATE_TABLE:
+ case SQLCOM_CREATE_SEQUENCE:
+ new_trg_event_map|= trg2bit(TRG_EVENT_INSERT);
+ break;
+ /* Basic update and multi-update */
+ case SQLCOM_UPDATE: /* fall through */
+ case SQLCOM_UPDATE_MULTI:
+ new_trg_event_map|= trg2bit(TRG_EVENT_UPDATE);
+ break;
+ /* Basic delete and multi-delete */
+ case SQLCOM_DELETE: /* fall through */
+ case SQLCOM_DELETE_MULTI:
+ new_trg_event_map|= trg2bit(TRG_EVENT_DELETE);
+ break;
+ default:
+ break;
+ }
+
+ switch (duplicates) {
+ case DUP_UPDATE:
+ new_trg_event_map|= trg2bit(TRG_EVENT_UPDATE);
+ break;
+ case DUP_REPLACE:
+ new_trg_event_map|= trg2bit(TRG_EVENT_DELETE);
+ break;
+ case DUP_ERROR:
+ default:
+ break;
+ }
+
+ if (period_conditions.is_set())
+ {
+ switch (sql_command)
+ {
+ case SQLCOM_DELETE:
+ case SQLCOM_UPDATE:
+ case SQLCOM_REPLACE:
+ new_trg_event_map |= trg2bit(TRG_EVENT_INSERT);
+ default:
+ break;
+ }
+ }
+
+
+ /*
+ Do not iterate over sub-selects, only the tables in the outermost
+ SELECT_LEX can be modified, if any.
+ */
+ TABLE_LIST *tables= first_select_lex()->get_table_list();
+
+ while (tables)
+ {
+ /*
+ This is a fast check to filter out statements that do
+ not change data, or tables on the right side, in case of
+ INSERT .. SELECT, CREATE TABLE .. SELECT and so on.
+ Here we also filter out OPTIMIZE statement and non-updateable
+ views, for which lock_type is TL_UNLOCK or TL_READ after
+ parsing.
+ */
+ if (static_cast<int>(tables->lock_type) >=
+ static_cast<int>(TL_WRITE_ALLOW_WRITE))
+ tables->trg_event_map= new_trg_event_map;
+ tables= tables->next_local;
+ }
+ DBUG_VOID_RETURN;
+}
+
+
+/*
+ Unlink the first table from the global table list and the first table from
+ outer select (lex->select_lex) local list
+
+ SYNOPSIS
+ unlink_first_table()
+ link_to_local Set to 1 if caller should link this table to local list
+
+ NOTES
+ We assume that first tables in both lists is the same table or the local
+ list is empty.
+
+ RETURN
+ 0 If 'query_tables' == 0
+ unlinked table
+ In this case link_to_local is set.
+
+*/
+TABLE_LIST *LEX::unlink_first_table(bool *link_to_local)
+{
+ TABLE_LIST *first;
+ if ((first= query_tables))
+ {
+ /*
+ Exclude from global table list
+ */
+ if ((query_tables= query_tables->next_global))
+ query_tables->prev_global= &query_tables;
+ else
+ query_tables_last= &query_tables;
+ first->next_global= 0;
+
+ /*
+ and from local list if it is not empty
+ */
+ if ((*link_to_local= MY_TEST(first_select_lex()->table_list.first)))
+ {
+ first_select_lex()->context.table_list=
+ first_select_lex()->context.first_name_resolution_table=
+ first->next_local;
+ first_select_lex()->table_list.first= first->next_local;
+ first_select_lex()->table_list.elements--; //safety
+ first->next_local= 0;
+ /*
+ Ensure that the global list has the same first table as the local
+ list.
+ */
+ first_lists_tables_same();
+ }
+ }
+ return first;
+}
+
+
+/*
+ Bring first local table of first most outer select to first place in global
+ table list
+
+ SYNOPSYS
+ LEX::first_lists_tables_same()
+
+ NOTES
+ In many cases (for example, usual INSERT/DELETE/...) the first table of
+ main SELECT_LEX have special meaning => check that it is the first table
+ in global list and re-link to be first in the global list if it is
+ necessary. We need such re-linking only for queries with sub-queries in
+ the select list, as only in this case tables of sub-queries will go to
+ the global list first.
+*/
+
+void LEX::first_lists_tables_same()
+{
+ TABLE_LIST *first_table= first_select_lex()->table_list.first;
+ if (query_tables != first_table && first_table != 0)
+ {
+ TABLE_LIST *next;
+ if (query_tables_last == &first_table->next_global)
+ query_tables_last= first_table->prev_global;
+
+ if (query_tables_own_last == &first_table->next_global)
+ query_tables_own_last= first_table->prev_global;
+
+ if ((next= *first_table->prev_global= first_table->next_global))
+ next->prev_global= first_table->prev_global;
+ /* include in new place */
+ first_table->next_global= query_tables;
+ /*
+ We are sure that query_tables is not 0, because first_table was not
+ first table in the global list => we can use
+ query_tables->prev_global without check of query_tables
+ */
+ query_tables->prev_global= &first_table->next_global;
+ first_table->prev_global= &query_tables;
+ query_tables= first_table;
+ }
+}
+
+void LEX::fix_first_select_number()
+{
+ SELECT_LEX *first= first_select_lex();
+ if (first && first->select_number != 1)
+ {
+ uint num= first->select_number;
+ for (SELECT_LEX *sel= all_selects_list;
+ sel;
+ sel= sel->next_select_in_list())
+ {
+ if (sel->select_number < num)
+ sel->select_number++;
+ }
+ first->select_number= 1;
+ }
+}
+
+
+/*
+ Link table back that was unlinked with unlink_first_table()
+
+ SYNOPSIS
+ link_first_table_back()
+ link_to_local do we need link this table to local
+
+ RETURN
+ global list
+*/
+
+void LEX::link_first_table_back(TABLE_LIST *first,
+ bool link_to_local)
+{
+ if (first)
+ {
+ if ((first->next_global= query_tables))
+ query_tables->prev_global= &first->next_global;
+ else
+ query_tables_last= &first->next_global;
+ query_tables= first;
+
+ if (link_to_local)
+ {
+ first->next_local= first_select_lex()->table_list.first;
+ first_select_lex()->context.table_list= first;
+ first_select_lex()->table_list.first= first;
+ first_select_lex()->table_list.elements++; //safety
+ }
+ }
+}
+
+
+
+/*
+ cleanup lex for case when we open table by table for processing
+
+ SYNOPSIS
+ LEX::cleanup_after_one_table_open()
+
+ NOTE
+ This method is mostly responsible for cleaning up of selects lists and
+ derived tables state. To rollback changes in Query_tables_list one has
+ to call Query_tables_list::reset_query_tables_list(FALSE).
+*/
+
+void LEX::cleanup_after_one_table_open()
+{
+ /*
+ thd->lex->derived_tables & additional units may be set if we open
+ a view. It is necessary to clear thd->lex->derived_tables flag
+ to prevent processing of derived tables during next open_and_lock_tables
+ if next table is a real table and cleanup & remove underlying units
+ NOTE: all units will be connected to thd->lex->select_lex, because we
+ have not UNION on most upper level.
+ */
+ if (all_selects_list != first_select_lex())
+ {
+ derived_tables= 0;
+ first_select_lex()->exclude_from_table_unique_test= false;
+ /* cleunup underlying units (units of VIEW) */
+ for (SELECT_LEX_UNIT *un= first_select_lex()->first_inner_unit();
+ un;
+ un= un->next_unit())
+ un->cleanup();
+ /* reduce all selects list to default state */
+ all_selects_list= first_select_lex();
+ /* remove underlying units (units of VIEW) subtree */
+ first_select_lex()->cut_subtree();
+ }
+}
+
+
+/*
+ Save current state of Query_tables_list for this LEX, and prepare it
+ for processing of new statemnt.
+
+ SYNOPSIS
+ reset_n_backup_query_tables_list()
+ backup Pointer to Query_tables_list instance to be used for backup
+*/
+
+void LEX::reset_n_backup_query_tables_list(Query_tables_list *backup)
+{
+ backup->set_query_tables_list(this);
+ /*
+ We have to perform full initialization here since otherwise we
+ will damage backed up state.
+ */
+ reset_query_tables_list(TRUE);
+}
+
+
+/*
+ Restore state of Query_tables_list for this LEX from backup.
+
+ SYNOPSIS
+ restore_backup_query_tables_list()
+ backup Pointer to Query_tables_list instance used for backup
+*/
+
+void LEX::restore_backup_query_tables_list(Query_tables_list *backup)
+{
+ destroy_query_tables_list();
+ set_query_tables_list(backup);
+}
+
+
+/*
+ Checks for usage of routines and/or tables in a parsed statement
+
+ SYNOPSIS
+ LEX:table_or_sp_used()
+
+ RETURN
+ FALSE No routines and tables used
+ TRUE Either or both routines and tables are used.
+*/
+
+bool LEX::table_or_sp_used()
+{
+ DBUG_ENTER("table_or_sp_used");
+
+ if (sroutines.records || query_tables)
+ DBUG_RETURN(TRUE);
+
+ DBUG_RETURN(FALSE);
+}
+
+
+/*
+ Do end-of-prepare fixup for list of tables and their merge-VIEWed tables
+
+ SYNOPSIS
+ fix_prepare_info_in_table_list()
+ thd Thread handle
+ tbl List of tables to process
+
+ DESCRIPTION
+ Perform end-end-of prepare fixup for list of tables, if any of the tables
+ is a merge-algorithm VIEW, recursively fix up its underlying tables as
+ well.
+
+*/
+
+static void fix_prepare_info_in_table_list(THD *thd, TABLE_LIST *tbl)
+{
+ for (; tbl; tbl= tbl->next_local)
+ {
+ if (tbl->on_expr && !tbl->prep_on_expr)
+ {
+ thd->check_and_register_item_tree(&tbl->prep_on_expr, &tbl->on_expr);
+ tbl->on_expr= tbl->on_expr->copy_andor_structure(thd);
+ }
+ if (tbl->is_view_or_derived() && tbl->is_merged_derived())
+ {
+ SELECT_LEX *sel= tbl->get_single_select();
+ fix_prepare_info_in_table_list(thd, sel->get_table_list());
+ }
+ }
+}
+
+
+/*
+ Save WHERE/HAVING/ON clauses and replace them with disposable copies
+
+ SYNOPSIS
+ st_select_lex::fix_prepare_information
+ thd thread handler
+ conds in/out pointer to WHERE condition to be met at execution
+ having_conds in/out pointer to HAVING condition to be met at execution
+
+ DESCRIPTION
+ The passed WHERE and HAVING are to be saved for the future executions.
+ This function saves it, and returns a copy which can be thrashed during
+ this execution of the statement. By saving/thrashing here we mean only
+ We also save the chain of ORDER::next in group_list, in case
+ the list is modified by remove_const().
+ AND/OR trees.
+ The function also calls fix_prepare_info_in_table_list that saves all
+ ON expressions.
+*/
+
+void st_select_lex::fix_prepare_information(THD *thd, Item **conds,
+ Item **having_conds)
+{
+ DBUG_ENTER("st_select_lex::fix_prepare_information");
+ if (!thd->stmt_arena->is_conventional() &&
+ !(changed_elements & TOUCHED_SEL_COND))
+ {
+ Query_arena_stmt on_stmt_arena(thd);
+ changed_elements|= TOUCHED_SEL_COND;
+ if (group_list.first)
+ {
+ if (!group_list_ptrs)
+ {
+ void *mem= thd->stmt_arena->alloc(sizeof(Group_list_ptrs));
+ group_list_ptrs= new (mem) Group_list_ptrs(thd->stmt_arena->mem_root);
+ }
+ group_list_ptrs->reserve(group_list.elements);
+ for (ORDER *order= group_list.first; order; order= order->next)
+ {
+ group_list_ptrs->push_back(order);
+ }
+ }
+ if (*conds)
+ {
+ thd->check_and_register_item_tree(&prep_where, conds);
+ *conds= where= prep_where->copy_andor_structure(thd);
+ }
+ if (*having_conds)
+ {
+ thd->check_and_register_item_tree(&prep_having, having_conds);
+ *having_conds= having= prep_having->copy_andor_structure(thd);
+ }
+ fix_prepare_info_in_table_list(thd, table_list.first);
+ }
+ DBUG_VOID_RETURN;
+}
+
+
+/*
+ There are st_select_lex::add_table_to_list &
+ st_select_lex::set_lock_for_tables are in sql_parse.cc
+
+ st_select_lex::print is in sql_select.cc
+
+ st_select_lex_unit::prepare, st_select_lex_unit::exec,
+ st_select_lex_unit::cleanup, st_select_lex_unit::reinit_exec_mechanism,
+ st_select_lex_unit::change_result
+ are in sql_union.cc
+*/
+
+/*
+ Sets the kind of hints to be added by the calls to add_index_hint().
+
+ SYNOPSIS
+ set_index_hint_type()
+ type_arg The kind of hints to be added from now on.
+ clause The clause to use for hints to be added from now on.
+
+ DESCRIPTION
+ Used in filling up the tagged hints list.
+ This list is filled by first setting the kind of the hint as a
+ context variable and then adding hints of the current kind.
+ Then the context variable index_hint_type can be reset to the
+ next hint type.
+*/
+void st_select_lex::set_index_hint_type(enum index_hint_type type_arg,
+ index_clause_map clause)
+{
+ current_index_hint_type= type_arg;
+ current_index_hint_clause= clause;
+}
+
+
+/*
+ Makes an array to store index usage hints (ADD/FORCE/IGNORE INDEX).
+
+ SYNOPSIS
+ alloc_index_hints()
+ thd current thread.
+*/
+
+void st_select_lex::alloc_index_hints (THD *thd)
+{
+ index_hints= new (thd->mem_root) List<Index_hint>();
+}
+
+
+
+/*
+ adds an element to the array storing index usage hints
+ (ADD/FORCE/IGNORE INDEX).
+
+ SYNOPSIS
+ add_index_hint()
+ thd current thread.
+ str name of the index.
+ length number of characters in str.
+
+ RETURN VALUE
+ 0 on success, non-zero otherwise
+*/
+bool st_select_lex::add_index_hint (THD *thd, const char *str, size_t length)
+{
+ return index_hints->push_front(new (thd->mem_root)
+ Index_hint(current_index_hint_type,
+ current_index_hint_clause,
+ str, length), thd->mem_root);
+}
+
+
+/**
+ Optimize all subqueries that have not been flattened into semi-joins.
+
+ @details
+ This functionality is a method of SELECT_LEX instead of JOIN because
+ SQL statements as DELETE/UPDATE do not have a corresponding JOIN object.
+
+ @see JOIN::optimize_unflattened_subqueries
+
+ @param const_only Restrict subquery optimization to constant subqueries
+
+ @return Operation status
+ @retval FALSE success.
+ @retval TRUE error occurred.
+*/
+
+bool st_select_lex::optimize_unflattened_subqueries(bool const_only)
+{
+ SELECT_LEX_UNIT *next_unit= NULL;
+ for (SELECT_LEX_UNIT *un= first_inner_unit();
+ un;
+ un= next_unit ? next_unit : un->next_unit())
+ {
+ Item_subselect *subquery_predicate= un->item;
+ next_unit= NULL;
+
+ if (subquery_predicate)
+ {
+ if (!subquery_predicate->fixed)
+ {
+ /*
+ This subquery was excluded as part of some expression so it is
+ invisible from all prepared expression.
+ */
+ next_unit= un->next_unit();
+ un->exclude_level();
+ if (next_unit)
+ continue;
+ break;
+ }
+ if (subquery_predicate->substype() == Item_subselect::IN_SUBS)
+ {
+ Item_in_subselect *in_subs= subquery_predicate->get_IN_subquery();
+ if (in_subs->is_jtbm_merged)
+ continue;
+ }
+
+ if (const_only && !subquery_predicate->const_item())
+ {
+ /* Skip non-constant subqueries if the caller asked so. */
+ continue;
+ }
+
+ bool empty_union_result= true;
+ bool is_correlated_unit= false;
+ bool first= true;
+ bool union_plan_saved= false;
+ /*
+ If the subquery is a UNION, optimize all the subqueries in the UNION. If
+ there is no UNION, then the loop will execute once for the subquery.
+ */
+ for (SELECT_LEX *sl= un->first_select(); sl; sl= sl->next_select())
+ {
+ JOIN *inner_join= sl->join;
+ if (first)
+ first= false;
+ else
+ {
+ if (!union_plan_saved)
+ {
+ union_plan_saved= true;
+ if (un->save_union_explain(un->thd->lex->explain))
+ return true; /* Failure */
+ }
+ }
+ if (!inner_join)
+ continue;
+ SELECT_LEX *save_select= un->thd->lex->current_select;
+ ulonglong save_options;
+ int res;
+ /* We need only 1 row to determine existence */
+ un->set_limit(un->global_parameters());
+ un->thd->lex->current_select= sl;
+ save_options= inner_join->select_options;
+ if (options & SELECT_DESCRIBE)
+ {
+ /* Optimize the subquery in the context of EXPLAIN. */
+ sl->set_explain_type(FALSE);
+ sl->options|= SELECT_DESCRIBE;
+ inner_join->select_options|= SELECT_DESCRIBE;
+ }
+ if ((res= inner_join->optimize()))
+ return TRUE;
+ if (!inner_join->cleaned)
+ sl->update_used_tables();
+ sl->update_correlated_cache();
+ is_correlated_unit|= sl->is_correlated;
+ inner_join->select_options= save_options;
+ un->thd->lex->current_select= save_select;
+
+ Explain_query *eq;
+ if ((eq= inner_join->thd->lex->explain))
+ {
+ Explain_select *expl_sel;
+ if ((expl_sel= eq->get_select(inner_join->select_lex->select_number)))
+ {
+ sl->set_explain_type(TRUE);
+ expl_sel->select_type= sl->type;
+ }
+ }
+
+ if (empty_union_result)
+ {
+ /*
+ If at least one subquery in a union is non-empty, the UNION result
+ is non-empty. If there is no UNION, the only subquery is non-empy.
+ */
+ empty_union_result= inner_join->empty_result();
+ }
+ if (res)
+ return TRUE;
+ }
+ if (empty_union_result)
+ subquery_predicate->no_rows_in_result();
+ if (!is_correlated_unit)
+ un->uncacheable&= ~UNCACHEABLE_DEPENDENT;
+ subquery_predicate->is_correlated= is_correlated_unit;
+ }
+ }
+ return FALSE;
+}
+
+
+
+/**
+ @brief Process all derived tables/views of the SELECT.
+
+ @param lex LEX of this thread
+ @param phase phases to run derived tables/views through
+
+ @details
+ This function runs specified 'phases' on all tables from the
+ table_list of this select.
+
+ @return FALSE ok.
+ @return TRUE an error occur.
+*/
+
+bool st_select_lex::handle_derived(LEX *lex, uint phases)
+{
+ return lex->handle_list_of_derived(table_list.first, phases);
+}
+
+
+/**
+ @brief
+ Returns first unoccupied table map and table number
+
+ @param map [out] return found map
+ @param tablenr [out] return found tablenr
+
+ @details
+ Returns first unoccupied table map and table number in this select.
+ Map and table are returned in *'map' and *'tablenr' accordingly.
+
+ @retrun TRUE no free table map/table number
+ @return FALSE found free table map/table number
+*/
+
+bool st_select_lex::get_free_table_map(table_map *map, uint *tablenr)
+{
+ *map= 0;
+ *tablenr= 0;
+ TABLE_LIST *tl;
+ List_iterator<TABLE_LIST> ti(leaf_tables);
+ while ((tl= ti++))
+ {
+ if (tl->table->map > *map)
+ *map= tl->table->map;
+ if (tl->table->tablenr > *tablenr)
+ *tablenr= tl->table->tablenr;
+ }
+ (*map)<<= 1;
+ (*tablenr)++;
+ if (*tablenr >= MAX_TABLES)
+ return TRUE;
+ return FALSE;
+}
+
+
+/**
+ @brief
+ Append given table to the leaf_tables list.
+
+ @param link Offset to which list in table structure to use
+ @param table Table to append
+
+ @details
+ Append given 'table' to the leaf_tables list using the 'link' offset.
+ If the 'table' is linked with other tables through next_leaf/next_local
+ chains then whole list will be appended.
+*/
+
+void st_select_lex::append_table_to_list(TABLE_LIST *TABLE_LIST::*link,
+ TABLE_LIST *table)
+{
+ TABLE_LIST *tl;
+ for (tl= leaf_tables.head(); tl->*link; tl= tl->*link) ;
+ tl->*link= table;
+}
+
+
+/*
+ @brief
+ Replace given table from the leaf_tables list for a list of tables
+
+ @param table Table to replace
+ @param list List to substititute the table for
+
+ @details
+ Replace 'table' from the leaf_tables list for a list of tables 'tbl_list'.
+*/
+
+void st_select_lex::replace_leaf_table(TABLE_LIST *table, List<TABLE_LIST> &tbl_list)
+{
+ TABLE_LIST *tl;
+ List_iterator<TABLE_LIST> ti(leaf_tables);
+ while ((tl= ti++))
+ {
+ if (tl == table)
+ {
+ ti.replace(tbl_list);
+ break;
+ }
+ }
+}
+
+
+/**
+ @brief
+ Assigns new table maps to tables in the leaf_tables list
+
+ @param derived Derived table to take initial table map from
+ @param map table map to begin with
+ @param tablenr table number to begin with
+ @param parent_lex new parent select_lex
+
+ @details
+ Assign new table maps/table numbers to all tables in the leaf_tables list.
+ 'map'/'tablenr' are used for the first table and shifted to left/
+ increased for each consequent table in the leaf_tables list.
+ If the 'derived' table is given then it's table map/number is used for the
+ first table in the list and 'map'/'tablenr' are used for the second and
+ all consequent tables.
+ The 'parent_lex' is set as the new parent select_lex for all tables in the
+ list.
+*/
+
+void st_select_lex::remap_tables(TABLE_LIST *derived, table_map map,
+ uint tablenr, SELECT_LEX *parent_lex)
+{
+ bool first_table= TRUE;
+ TABLE_LIST *tl;
+ table_map first_map;
+ uint first_tablenr;
+
+ if (derived && derived->table)
+ {
+ first_map= derived->table->map;
+ first_tablenr= derived->table->tablenr;
+ }
+ else
+ {
+ first_map= map;
+ map<<= 1;
+ first_tablenr= tablenr++;
+ }
+ /*
+ Assign table bit/table number.
+ To the first table of the subselect the table bit/tablenr of the
+ derived table is assigned. The rest of tables are getting bits
+ sequentially, starting from the provided table map/tablenr.
+ */
+ List_iterator<TABLE_LIST> ti(leaf_tables);
+ while ((tl= ti++))
+ {
+ if (first_table)
+ {
+ first_table= FALSE;
+ tl->table->set_table_map(first_map, first_tablenr);
+ }
+ else
+ {
+ tl->table->set_table_map(map, tablenr);
+ tablenr++;
+ map<<= 1;
+ }
+ SELECT_LEX *old_sl= tl->select_lex;
+ tl->select_lex= parent_lex;
+ for(TABLE_LIST *emb= tl->embedding;
+ emb && emb->select_lex == old_sl;
+ emb= emb->embedding)
+ emb->select_lex= parent_lex;
+ }
+}
+
+/**
+ @brief
+ Merge a subquery into this select.
+
+ @param derived derived table of the subquery to be merged
+ @param subq_select select_lex of the subquery
+ @param map table map for assigning to merged tables from subquery
+ @param table_no table number for assigning to merged tables from subquery
+
+ @details
+ This function merges a subquery into its parent select. In short the
+ merge operation appends the subquery FROM table list to the parent's
+ FROM table list. In more details:
+ .) the top_join_list of the subquery is wrapped into a join_nest
+ and attached to 'derived'
+ .) subquery's leaf_tables list is merged with the leaf_tables
+ list of this select_lex
+ .) the table maps and table numbers of the tables merged from
+ the subquery are adjusted to reflect their new binding to
+ this select
+
+ @return TRUE an error occur
+ @return FALSE ok
+*/
+
+bool SELECT_LEX::merge_subquery(THD *thd, TABLE_LIST *derived,
+ SELECT_LEX *subq_select,
+ uint table_no, table_map map)
+{
+ derived->wrap_into_nested_join(subq_select->top_join_list);
+
+ ftfunc_list->append(subq_select->ftfunc_list);
+ if (join ||
+ thd->lex->sql_command == SQLCOM_UPDATE_MULTI ||
+ thd->lex->sql_command == SQLCOM_DELETE_MULTI)
+ {
+ List_iterator_fast<Item_in_subselect> li(subq_select->sj_subselects);
+ Item_in_subselect *in_subq;
+ while ((in_subq= li++))
+ {
+ sj_subselects.push_back(in_subq, thd->mem_root);
+ if (in_subq->emb_on_expr_nest == NO_JOIN_NEST)
+ in_subq->emb_on_expr_nest= derived;
+ }
+
+ uint cnt= sizeof(expr_cache_may_be_used)/sizeof(bool);
+ for (uint i= 0; i < cnt; i++)
+ {
+ if (subq_select->expr_cache_may_be_used[i])
+ expr_cache_may_be_used[i]= true;
+ }
+
+ List_iterator_fast<Item_func_in> it(subq_select->in_funcs);
+ Item_func_in *in_func;
+ while ((in_func= it++))
+ {
+ in_funcs.push_back(in_func, thd->mem_root);
+ if (in_func->emb_on_expr_nest == NO_JOIN_NEST)
+ in_func->emb_on_expr_nest= derived;
+ }
+ }
+
+ /* Walk through child's tables and adjust table map, tablenr,
+ * parent_lex */
+ subq_select->remap_tables(derived, map, table_no, this);
+ subq_select->merged_into= this;
+
+ replace_leaf_table(derived, subq_select->leaf_tables);
+
+ return FALSE;
+}
+
+
+/**
+ @brief
+ Mark tables from the leaf_tables list as belong to a derived table.
+
+ @param derived tables will be marked as belonging to this derived
+
+ @details
+ Run through the leaf_list and mark all tables as belonging to the 'derived'.
+*/
+
+void SELECT_LEX::mark_as_belong_to_derived(TABLE_LIST *derived)
+{
+ /* Mark tables as belonging to this DT */
+ TABLE_LIST *tl;
+ List_iterator<TABLE_LIST> ti(leaf_tables);
+ while ((tl= ti++))
+ tl->belong_to_derived= derived;
+}
+
+
+/**
+ @brief
+ Update used_tables cache for this select
+
+ @details
+ This function updates used_tables cache of ON expressions of all tables
+ in the leaf_tables list and of the conds expression (if any).
+*/
+
+void SELECT_LEX::update_used_tables()
+{
+ TABLE_LIST *tl;
+ List_iterator<TABLE_LIST> ti(leaf_tables);
+
+ while ((tl= ti++))
+ {
+ if (tl->table && !tl->is_view_or_derived())
+ {
+ TABLE_LIST *embedding= tl->embedding;
+ for (embedding= tl->embedding; embedding; embedding=embedding->embedding)
+ {
+ if (embedding->is_view_or_derived())
+ {
+ DBUG_ASSERT(embedding->is_merged_derived());
+ TABLE *tab= tl->table;
+ tab->covering_keys= tab->s->keys_for_keyread;
+ tab->covering_keys.intersect(tab->keys_in_use_for_query);
+ /*
+ View/derived was merged. Need to recalculate read_set
+ bitmaps here. For example:
+ CREATE VIEW v1 AS SELECT f1,f2,f3 FROM t1;
+ SELECT f1 FROM v1;
+ Initially, the view definition will put all f1,f2,f3 in the
+ read_set for t1. But after the view is merged, only f1 should
+ be in the read_set.
+ */
+ bitmap_clear_all(tab->read_set);
+ break;
+ }
+ }
+ }
+ }
+
+ ti.rewind();
+ while ((tl= ti++))
+ {
+ TABLE_LIST *embedding= tl;
+ do
+ {
+ bool maybe_null;
+ if ((maybe_null= MY_TEST(embedding->outer_join)))
+ {
+ tl->table->maybe_null= maybe_null;
+ break;
+ }
+ }
+ while ((embedding= embedding->embedding));
+ if (tl->on_expr)
+ {
+ tl->on_expr->update_used_tables();
+ tl->on_expr->walk(&Item::eval_not_null_tables, 0, NULL);
+ }
+ /*
+ - There is no need to check sj_on_expr, because merged semi-joins inject
+ sj_on_expr into the parent's WHERE clase.
+ - For non-merged semi-joins (aka JTBMs), we need to check their
+ left_expr. There is no need to check the rest of the subselect, we know
+ it is uncorrelated and so cannot refer to any tables in this select.
+ */
+ if (tl->jtbm_subselect)
+ {
+ Item *left_expr= tl->jtbm_subselect->left_exp();
+ left_expr->walk(&Item::update_table_bitmaps_processor, FALSE, NULL);
+ }
+
+ embedding= tl->embedding;
+ while (embedding)
+ {
+ if (embedding->on_expr &&
+ embedding->nested_join->join_list.head() == tl)
+ {
+ embedding->on_expr->update_used_tables();
+ embedding->on_expr->walk(&Item::eval_not_null_tables, 0, NULL);
+ }
+ tl= embedding;
+ embedding= tl->embedding;
+ }
+ }
+
+ if (join->conds)
+ {
+ join->conds->update_used_tables();
+ join->conds->walk(&Item::eval_not_null_tables, 0, NULL);
+ }
+ if (join->having)
+ {
+ join->having->update_used_tables();
+ }
+
+ Item *item;
+ List_iterator_fast<Item> it(join->all_fields);
+ select_list_tables= 0;
+ while ((item= it++))
+ {
+ item->update_used_tables();
+ select_list_tables|= item->used_tables();
+ }
+ Item_outer_ref *ref;
+ List_iterator_fast<Item_outer_ref> ref_it(inner_refs_list);
+ while ((ref= ref_it++))
+ {
+ item= ref->outer_ref;
+ item->update_used_tables();
+ }
+ for (ORDER *order= group_list.first; order; order= order->next)
+ (*order->item)->update_used_tables();
+ if (!master_unit()->is_unit_op() ||
+ master_unit()->global_parameters() != this)
+ {
+ for (ORDER *order= order_list.first; order; order= order->next)
+ (*order->item)->update_used_tables();
+ }
+ join->result->update_used_tables();
+}
+
+
+/**
+ @brief
+ Update is_correlated cache for this select
+
+ @details
+*/
+
+void st_select_lex::update_correlated_cache()
+{
+ TABLE_LIST *tl;
+ List_iterator<TABLE_LIST> ti(leaf_tables);
+
+ is_correlated= false;
+
+ while ((tl= ti++))
+ {
+ // is_correlated|= tl->is_with_table_recursive_reference();
+ if (tl->on_expr)
+ is_correlated|= MY_TEST(tl->on_expr->used_tables() & OUTER_REF_TABLE_BIT);
+ for (TABLE_LIST *embedding= tl->embedding ; embedding ;
+ embedding= embedding->embedding)
+ {
+ if (embedding->on_expr)
+ is_correlated|= MY_TEST(embedding->on_expr->used_tables() &
+ OUTER_REF_TABLE_BIT);
+ }
+ }
+
+ if (join->conds)
+ is_correlated|= MY_TEST(join->conds->used_tables() & OUTER_REF_TABLE_BIT);
+
+ is_correlated|= join->having_is_correlated;
+
+ if (join->having)
+ is_correlated|= MY_TEST(join->having->used_tables() & OUTER_REF_TABLE_BIT);
+
+ if (join->tmp_having)
+ is_correlated|= MY_TEST(join->tmp_having->used_tables() &
+ OUTER_REF_TABLE_BIT);
+
+ Item *item;
+ List_iterator_fast<Item> it(join->fields_list);
+ while ((item= it++))
+ is_correlated|= MY_TEST(item->used_tables() & OUTER_REF_TABLE_BIT);
+
+ for (ORDER *order= group_list.first; order; order= order->next)
+ is_correlated|= MY_TEST((*order->item)->used_tables() &
+ OUTER_REF_TABLE_BIT);
+
+ if (!master_unit()->is_unit_op())
+ {
+ for (ORDER *order= order_list.first; order; order= order->next)
+ is_correlated|= MY_TEST((*order->item)->used_tables() &
+ OUTER_REF_TABLE_BIT);
+ }
+
+ if (!is_correlated)
+ uncacheable&= ~UNCACHEABLE_DEPENDENT;
+}
+
+
+/**
+ Set the EXPLAIN type for this subquery.
+
+ @param on_the_fly TRUE<=> We're running a SHOW EXPLAIN command, so we must
+ not change any variables
+*/
+
+void st_select_lex::set_explain_type(bool on_the_fly)
+{
+ bool is_primary= FALSE;
+ if (next_select())
+ is_primary= TRUE;
+
+ if (!is_primary && first_inner_unit())
+ {
+ /*
+ If there is at least one materialized derived|view then it's a PRIMARY select.
+ Otherwise, all derived tables/views were merged and this select is a SIMPLE one.
+ */
+ for (SELECT_LEX_UNIT *un= first_inner_unit(); un; un= un->next_unit())
+ {
+ if ((!un->derived || un->derived->is_materialized_derived()))
+ {
+ is_primary= TRUE;
+ break;
+ }
+ }
+ }
+
+ if (on_the_fly && !is_primary && have_merged_subqueries)
+ is_primary= TRUE;
+
+ SELECT_LEX *first= master_unit()->first_select();
+ /* drop UNCACHEABLE_EXPLAIN, because it is for internal usage only */
+ uint8 is_uncacheable= (uncacheable & ~UNCACHEABLE_EXPLAIN);
+
+ bool using_materialization= FALSE;
+ Item_subselect *parent_item;
+ if ((parent_item= master_unit()->item) &&
+ parent_item->substype() == Item_subselect::IN_SUBS)
+ {
+ Item_in_subselect *in_subs= parent_item->get_IN_subquery();
+ /*
+ Surprisingly, in_subs->is_set_strategy() can return FALSE here,
+ even for the last invocation of this function for the select.
+ */
+ if (in_subs->test_strategy(SUBS_MATERIALIZATION))
+ using_materialization= TRUE;
+ }
+
+ if (master_unit()->thd->lex->first_select_lex() == this)
+ {
+ if (pushdown_select)
+ type= pushed_select_text;
+ else
+ type= is_primary ? "PRIMARY" : "SIMPLE";
+ }
+ else
+ {
+ if (this == first)
+ {
+ /* If we're a direct child of a UNION, we're the first sibling there */
+ if (linkage == DERIVED_TABLE_TYPE)
+ {
+ bool is_pushed_master_unit= master_unit()->derived &&
+ master_unit()->derived->pushdown_derived;
+ if (is_pushed_master_unit)
+ type= pushed_derived_text;
+ else if (is_uncacheable & UNCACHEABLE_DEPENDENT)
+ type= "LATERAL DERIVED";
+ else
+ type= "DERIVED";
+ }
+ else if (using_materialization)
+ type= "MATERIALIZED";
+ else
+ {
+ if (is_uncacheable & UNCACHEABLE_DEPENDENT)
+ type= "DEPENDENT SUBQUERY";
+ else
+ {
+ type= is_uncacheable? "UNCACHEABLE SUBQUERY" :
+ "SUBQUERY";
+ }
+ }
+ }
+ else
+ {
+ switch (linkage)
+ {
+ case INTERSECT_TYPE:
+ type= "INTERSECT";
+ break;
+ case EXCEPT_TYPE:
+ type= "EXCEPT";
+ break;
+ default:
+ /* This a non-first sibling in UNION */
+ if (is_uncacheable & UNCACHEABLE_DEPENDENT)
+ type= "DEPENDENT UNION";
+ else if (using_materialization)
+ type= "MATERIALIZED UNION";
+ else
+ {
+ type= is_uncacheable ? "UNCACHEABLE UNION": "UNION";
+ if (this == master_unit()->fake_select_lex)
+ type= unit_operation_text[master_unit()->common_op()];
+ /*
+ join below may be =NULL when this functions is called at an early
+ stage. It will be later called again and we will set the correct
+ value.
+ */
+ if (join)
+ {
+ bool uses_cte= false;
+ for (JOIN_TAB *tab= first_linear_tab(join, WITHOUT_BUSH_ROOTS,
+ WITH_CONST_TABLES);
+ tab;
+ tab= next_linear_tab(join, tab, WITHOUT_BUSH_ROOTS))
+ {
+ /*
+ pos_in_table_list=NULL for e.g. post-join aggregation JOIN_TABs.
+ */
+ if (!(tab->table && tab->table->pos_in_table_list))
+ continue;
+ TABLE_LIST *tbl= tab->table->pos_in_table_list;
+ if (tbl->with && tbl->with->is_recursive &&
+ tbl->is_with_table_recursive_reference())
+ {
+ uses_cte= true;
+ break;
+ }
+ }
+ if (uses_cte)
+ type= "RECURSIVE UNION";
+ }
+ }
+ break;
+ }
+ }
+ }
+
+ if (!on_the_fly)
+ options|= SELECT_DESCRIBE;
+}
+
+
+/**
+ @brief
+ Increase estimated number of records for a derived table/view
+
+ @param records number of records to increase estimate by
+
+ @details
+ This function increases estimated number of records by the 'records'
+ for the derived table to which this select belongs to.
+*/
+
+void SELECT_LEX::increase_derived_records(ha_rows records)
+{
+ SELECT_LEX_UNIT *unit= master_unit();
+ DBUG_ASSERT(unit->derived);
+
+ if (unit->with_element && unit->with_element->is_recursive)
+ {
+ st_select_lex *first_recursive= unit->with_element->first_recursive;
+ st_select_lex *sl= unit->first_select();
+ for ( ; sl != first_recursive; sl= sl->next_select())
+ {
+ if (sl == this)
+ break;
+ }
+ if (sl == first_recursive)
+ return;
+ }
+
+ select_result *result= unit->result;
+ switch (linkage)
+ {
+ case INTERSECT_TYPE:
+ // result of intersect can't be more then one of components
+ set_if_smaller(result->est_records, records);
+ case EXCEPT_TYPE:
+ // in worse case none of record will be removed
+ break;
+ default:
+ // usual UNION
+ if (HA_ROWS_MAX - records > result->est_records)
+ result->est_records+= records;
+ else
+ result->est_records= HA_ROWS_MAX;
+ break;
+ }
+}
+
+
+/**
+ @brief
+ Mark select's derived table as a const one.
+
+ @param empty Whether select has an empty result set
+
+ @details
+ Mark derived table/view of this select as a constant one (to
+ materialize it at the optimization phase) unless this select belongs to a
+ union. Estimated number of rows is incremented if this select has non empty
+ result set.
+*/
+
+void SELECT_LEX::mark_const_derived(bool empty)
+{
+ TABLE_LIST *derived= master_unit()->derived;
+ /* join == NULL in DELETE ... RETURNING */
+ if (!(join && join->thd->lex->describe) && derived)
+ {
+ if (!empty)
+ increase_derived_records(1);
+ if (!master_unit()->is_unit_op() && !derived->is_merged_derived() &&
+ !(join && join->with_two_phase_optimization))
+ derived->fill_me= TRUE;
+ }
+}
+
+
+bool st_select_lex::save_leaf_tables(THD *thd)
+{
+ Query_arena *arena, backup;
+ arena= thd->activate_stmt_arena_if_needed(&backup);
+
+ List_iterator_fast<TABLE_LIST> li(leaf_tables);
+ TABLE_LIST *table;
+ while ((table= li++))
+ {
+ if (leaf_tables_exec.push_back(table, thd->mem_root))
+ return 1;
+ table->tablenr_exec= table->get_tablenr();
+ table->map_exec= table->get_map();
+ if (join && (join->select_options & SELECT_DESCRIBE))
+ table->maybe_null_exec= 0;
+ else
+ table->maybe_null_exec= table->table? table->table->maybe_null: 0;
+ }
+ if (arena)
+ thd->restore_active_arena(arena, &backup);
+
+ return 0;
+}
+
+
+bool LEX::save_prep_leaf_tables()
+{
+ if (!thd->save_prep_leaf_list)
+ return FALSE;
+
+ Query_arena *arena= thd->stmt_arena, backup;
+ arena= thd->activate_stmt_arena_if_needed(&backup);
+ //It is used for DETETE/UPDATE so top level has only one SELECT
+ DBUG_ASSERT(first_select_lex()->next_select() == NULL);
+ bool res= first_select_lex()->save_prep_leaf_tables(thd);
+
+ if (arena)
+ thd->restore_active_arena(arena, &backup);
+
+ if (res)
+ return TRUE;
+
+ thd->save_prep_leaf_list= FALSE;
+ return FALSE;
+}
+
+
+bool st_select_lex::save_prep_leaf_tables(THD *thd)
+{
+ if (prep_leaf_list_state == SAVED)
+ return FALSE;
+
+ List_iterator_fast<TABLE_LIST> li(leaf_tables);
+ TABLE_LIST *table;
+
+ /*
+ Check that the SELECT_LEX was really prepared and so tables are setup.
+
+ It can be subquery in SET clause of UPDATE which was not prepared yet, so
+ its tables are not yet setup and ready for storing.
+ */
+ if (prep_leaf_list_state != READY)
+ return FALSE;
+
+ while ((table= li++))
+ {
+ if (leaf_tables_prep.push_back(table))
+ return TRUE;
+ }
+ prep_leaf_list_state= SAVED;
+ for (SELECT_LEX_UNIT *u= first_inner_unit(); u; u= u->next_unit())
+ {
+ for (SELECT_LEX *sl= u->first_select(); sl; sl= sl->next_select())
+ {
+ if (sl->save_prep_leaf_tables(thd))
+ return TRUE;
+ }
+ }
+
+ return FALSE;
+}
+
+
+/**
+ Set exclude_from_table_unique_test for selects of this select and all selects
+ belonging to the underlying units of derived tables or views
+*/
+
+void st_select_lex::set_unique_exclude()
+{
+ exclude_from_table_unique_test= TRUE;
+ for (SELECT_LEX_UNIT *unit= first_inner_unit();
+ unit;
+ unit= unit->next_unit())
+ {
+ if (unit->derived && unit->derived->is_view_or_derived())
+ {
+ for (SELECT_LEX *sl= unit->first_select(); sl; sl= sl->next_select())
+ sl->set_unique_exclude();
+ }
+ }
+}
+
+
+/*
+ Return true if this select_lex has been converted into a semi-join nest
+ within 'ancestor'.
+
+ We need a loop to check this because there could be several nested
+ subselects, like
+
+ SELECT ... FROM grand_parent
+ WHERE expr1 IN (SELECT ... FROM parent
+ WHERE expr2 IN ( SELECT ... FROM child)
+
+ which were converted into:
+
+ SELECT ...
+ FROM grand_parent SEMI_JOIN (parent JOIN child)
+ WHERE
+ expr1 AND expr2
+
+ In this case, both parent and child selects were merged into the parent.
+*/
+
+bool st_select_lex::is_merged_child_of(st_select_lex *ancestor)
+{
+ bool all_merged= TRUE;
+ for (SELECT_LEX *sl= this; sl && sl!=ancestor;
+ sl=sl->outer_select())
+ {
+ Item *subs= sl->master_unit()->item;
+ Item_in_subselect *in_subs= (subs ? subs->get_IN_subquery() : NULL);
+ if (in_subs &&
+ ((Item_subselect*)subs)->substype() == Item_subselect::IN_SUBS &&
+ in_subs->test_strategy(SUBS_SEMI_JOIN))
+ {
+ continue;
+ }
+
+ if (sl->master_unit()->derived &&
+ sl->master_unit()->derived->is_merged_derived())
+ {
+ continue;
+ }
+ all_merged= FALSE;
+ break;
+ }
+ return all_merged;
+}
+
+/*
+ This is used by SHOW EXPLAIN. It assuses query plan has been already
+ collected into QPF structures and we only need to print it out.
+*/
+
+int LEX::print_explain(select_result_sink *output, uint8 explain_flags,
+ bool is_analyze, bool *printed_anything)
+{
+ int res;
+ if (explain && explain->have_query_plan())
+ {
+ res= explain->print_explain(output, explain_flags, is_analyze);
+ *printed_anything= true;
+ }
+ else
+ {
+ res= 0;
+ *printed_anything= false;
+ }
+ return res;
+}
+
+
+/**
+ Allocates and set arena for SET STATEMENT old values.
+
+ @param backup where to save backup of arena.
+
+ @retval 1 Error
+ @retval 0 OK
+*/
+
+bool LEX::set_arena_for_set_stmt(Query_arena *backup)
+{
+ DBUG_ENTER("LEX::set_arena_for_set_stmt");
+ DBUG_ASSERT(arena_for_set_stmt== 0);
+ if (!mem_root_for_set_stmt)
+ {
+ mem_root_for_set_stmt= new MEM_ROOT();
+ if (unlikely(!(mem_root_for_set_stmt)))
+ DBUG_RETURN(1);
+ init_sql_alloc(PSI_INSTRUMENT_ME, mem_root_for_set_stmt, ALLOC_ROOT_SET,
+ ALLOC_ROOT_SET, MYF(MY_THREAD_SPECIFIC));
+ }
+ if (unlikely(!(arena_for_set_stmt= new(mem_root_for_set_stmt)
+ Query_arena_memroot(mem_root_for_set_stmt,
+ Query_arena::STMT_INITIALIZED))))
+ DBUG_RETURN(1);
+ DBUG_PRINT("info", ("mem_root: %p arena: %p",
+ mem_root_for_set_stmt,
+ arena_for_set_stmt));
+ thd->set_n_backup_active_arena(arena_for_set_stmt, backup);
+ DBUG_RETURN(0);
+}
+
+
+void LEX::reset_arena_for_set_stmt(Query_arena *backup)
+{
+ DBUG_ENTER("LEX::reset_arena_for_set_stmt");
+ DBUG_ASSERT(arena_for_set_stmt);
+ thd->restore_active_arena(arena_for_set_stmt, backup);
+ DBUG_PRINT("info", ("mem_root: %p arena: %p",
+ arena_for_set_stmt->mem_root,
+ arena_for_set_stmt));
+ DBUG_VOID_RETURN;
+}
+
+
+void LEX::free_arena_for_set_stmt()
+{
+ DBUG_ENTER("LEX::free_arena_for_set_stmt");
+ if (!arena_for_set_stmt)
+ return;
+ DBUG_PRINT("info", ("mem_root: %p arena: %p",
+ arena_for_set_stmt->mem_root,
+ arena_for_set_stmt));
+ arena_for_set_stmt->free_items();
+ delete(arena_for_set_stmt);
+ free_root(mem_root_for_set_stmt, MYF(MY_KEEP_PREALLOC));
+ arena_for_set_stmt= 0;
+ DBUG_VOID_RETURN;
+}
+
+void LEX::restore_set_statement_var()
+{
+ DBUG_ENTER("LEX::restore_set_statement_var");
+ if (!old_var_list.is_empty())
+ {
+ DBUG_PRINT("info", ("vars: %d", old_var_list.elements));
+ sql_set_variables(thd, &old_var_list, false);
+ old_var_list.empty();
+ free_arena_for_set_stmt();
+ }
+ DBUG_ASSERT(!is_arena_for_set_stmt());
+ DBUG_VOID_RETURN;
+}
+
+unit_common_op st_select_lex_unit::common_op()
+{
+ SELECT_LEX *first= first_select();
+ bool first_op= TRUE;
+ unit_common_op operation= OP_MIX; // if no op
+ for (SELECT_LEX *sl= first; sl; sl= sl->next_select())
+ {
+ if (sl != first)
+ {
+ unit_common_op op;
+ switch (sl->linkage)
+ {
+ case INTERSECT_TYPE:
+ op= OP_INTERSECT;
+ break;
+ case EXCEPT_TYPE:
+ op= OP_EXCEPT;
+ break;
+ default:
+ op= OP_UNION;
+ break;
+ }
+ if (first_op)
+ {
+ operation= op;
+ first_op= FALSE;
+ }
+ else
+ {
+ if (operation != op)
+ operation= OP_MIX;
+ }
+ }
+ }
+ return operation;
+}
+/*
+ Save explain structures of a UNION. The only variable member is whether the
+ union has "Using filesort".
+
+ There is also save_union_explain_part2() function, which is called before we read
+ UNION's output.
+
+ The reason for it is examples like this:
+
+ SELECT col1 FROM t1 UNION SELECT col2 FROM t2 ORDER BY (select ... from t3 ...)
+
+ Here, the (select ... from t3 ...) subquery must be a child of UNION's
+ st_select_lex. However, it is not connected as child until a very late
+ stage in execution.
+*/
+
+int st_select_lex_unit::save_union_explain(Explain_query *output)
+{
+ SELECT_LEX *first= first_select();
+
+ if (output->get_union(first->select_number))
+ return 0; /* Already added */
+
+ Explain_union *eu=
+ new (output->mem_root) Explain_union(output->mem_root,
+ thd->lex->analyze_stmt);
+ if (unlikely(!eu))
+ return 0;
+
+ if (with_element && with_element->is_recursive)
+ eu->is_recursive_cte= true;
+
+ if (derived)
+ eu->connection_type= Explain_node::EXPLAIN_NODE_DERIVED;
+ /*
+ Note: Non-merged semi-joins cannot be made out of UNIONs currently, so we
+ don't ever set EXPLAIN_NODE_NON_MERGED_SJ.
+ */
+ for (SELECT_LEX *sl= first; sl; sl= sl->next_select())
+ eu->add_select(sl->select_number);
+
+ eu->fake_select_type= unit_operation_text[eu->operation= common_op()];
+ eu->using_filesort= MY_TEST(global_parameters()->order_list.first);
+ eu->using_tmp= union_needs_tmp_table();
+
+ // Save the UNION node
+ output->add_node(eu);
+
+ if (eu->get_select_id() == 1)
+ output->query_plan_ready();
+
+ return 0;
+}
+
+
+/*
+ @see st_select_lex_unit::save_union_explain
+*/
+
+int st_select_lex_unit::save_union_explain_part2(Explain_query *output)
+{
+ Explain_union *eu= output->get_union(first_select()->select_number);
+ if (fake_select_lex)
+ {
+ for (SELECT_LEX_UNIT *unit= fake_select_lex->first_inner_unit();
+ unit; unit= unit->next_unit())
+ {
+ if (unit->explainable())
+ eu->add_child(unit->first_select()->select_number);
+ }
+ fake_select_lex->join->explain= &eu->fake_select_lex_explain;
+ }
+ return 0;
+}
+
+
+/**
+ A routine used by the parser to decide whether we are specifying a full
+ partitioning or if only partitions to add or to split.
+
+ @note This needs to be outside of WITH_PARTITION_STORAGE_ENGINE since it
+ is used from the sql parser that doesn't have any ifdef's
+
+ @retval TRUE Yes, it is part of a management partition command
+ @retval FALSE No, not a management partition command
+*/
+
+bool LEX::is_partition_management() const
+{
+ return (sql_command == SQLCOM_ALTER_TABLE &&
+ (alter_info.partition_flags == ALTER_PARTITION_ADD ||
+ alter_info.partition_flags == ALTER_PARTITION_REORGANIZE));
+}
+
+
+/**
+ Exclude last added SELECT_LEX (current) in the UNIT and return pointer in it
+ (previous become currect)
+
+ @return detached SELECT_LEX or NULL in case of error
+*/
+
+SELECT_LEX *LEX::exclude_last_select()
+{
+ return exclude_not_first_select(current_select);
+}
+
+SELECT_LEX *LEX::exclude_not_first_select(SELECT_LEX *exclude)
+{
+ DBUG_ENTER("LEX::exclude_not_first_select");
+ DBUG_PRINT("enter", ("exclude %p #%u", exclude, exclude->select_number));
+ SELECT_LEX_UNIT *unit= exclude->master_unit();
+ SELECT_LEX *sl;
+ DBUG_ASSERT(unit->first_select() != exclude);
+ /* we should go through the list to correctly set current_select */
+ for(sl= unit->first_select();
+ sl->next_select() && sl->next_select() != exclude;
+ sl= sl->next_select());
+ DBUG_PRINT("info", ("excl: %p unit: %p prev: %p", exclude, unit, sl));
+ if (!sl)
+ DBUG_RETURN(NULL);
+ DBUG_ASSERT(&sl->next == exclude->prev);
+
+ exclude->prev= NULL;
+
+ current_select= sl;
+ DBUG_RETURN(exclude);
+}
+
+
+SELECT_LEX_UNIT *LEX::alloc_unit()
+{
+ SELECT_LEX_UNIT *unit;
+ DBUG_ENTER("LEX::alloc_unit");
+ if (!(unit= new (thd->mem_root) SELECT_LEX_UNIT()))
+ DBUG_RETURN(NULL);
+
+ unit->init_query();
+ /* TODO: reentrant problem */
+ unit->thd= thd;
+ unit->link_next= 0;
+ unit->link_prev= 0;
+ /* TODO: remove return_to */
+ unit->return_to= NULL;
+ DBUG_RETURN(unit);
+}
+
+
+SELECT_LEX *LEX::alloc_select(bool select)
+{
+ SELECT_LEX *select_lex;
+ DBUG_ENTER("LEX::alloc_select");
+ if (!(select_lex= new (thd->mem_root) SELECT_LEX()))
+ DBUG_RETURN(NULL);
+ DBUG_PRINT("info", ("Allocate select: %p #%u statement lex: %p",
+ select_lex, thd->lex->stmt_lex->current_select_number,
+ thd->lex->stmt_lex));
+ /*
+ TODO: move following init to constructor when we get rid of builtin
+ select
+ */
+ select_lex->select_number= ++thd->lex->stmt_lex->current_select_number;
+ select_lex->parent_lex= this; /* Used in init_query. */
+ select_lex->init_query();
+ if (select)
+ select_lex->init_select();
+ select_lex->nest_level_base= &this->unit;
+ select_lex->include_global((st_select_lex_node**)&all_selects_list);
+ select_lex->context.resolve_in_select_list= TRUE;
+ DBUG_RETURN(select_lex);
+}
+
+SELECT_LEX_UNIT *
+LEX::create_unit(SELECT_LEX *first_sel)
+{
+ SELECT_LEX_UNIT *unit;
+ DBUG_ENTER("LEX::create_unit");
+
+ unit = first_sel->master_unit();
+
+ if (!unit && !(unit= alloc_unit()))
+ DBUG_RETURN(NULL);
+
+ unit->register_select_chain(first_sel);
+ if (first_sel->next_select())
+ {
+ unit->reset_distinct();
+ DBUG_ASSERT(!unit->fake_select_lex);
+ if (unit->add_fake_select_lex(thd))
+ DBUG_RETURN(NULL);
+ }
+ DBUG_RETURN(unit);
+}
+
+SELECT_LEX_UNIT *
+SELECT_LEX::attach_selects_chain(SELECT_LEX *first_sel,
+ Name_resolution_context *context)
+{
+ SELECT_LEX_UNIT *unit;
+ DBUG_ENTER("SELECT_LEX::attach_select_chain");
+
+ if (!(unit= parent_lex->alloc_unit()))
+ DBUG_RETURN(NULL);
+
+ unit->register_select_chain(first_sel);
+ register_unit(unit, context);
+ if (first_sel->next_select())
+ {
+ unit->reset_distinct();
+ DBUG_ASSERT(!unit->fake_select_lex);
+ if (unit->add_fake_select_lex(parent_lex->thd))
+ DBUG_RETURN(NULL);
+ }
+
+ DBUG_RETURN(unit);
+}
+
+SELECT_LEX *
+LEX::wrap_unit_into_derived(SELECT_LEX_UNIT *unit)
+{
+ SELECT_LEX *wrapping_sel;
+ Table_ident *ti;
+ DBUG_ENTER("LEX::wrap_unit_into_derived");
+
+ if (!(wrapping_sel= alloc_select(TRUE)))
+ DBUG_RETURN(NULL);
+ Name_resolution_context *context= &wrapping_sel->context;
+ context->init();
+ wrapping_sel->automatic_brackets= FALSE;
+ wrapping_sel->mark_as_unit_nest();
+ wrapping_sel->register_unit(unit, context);
+
+ /* stuff dummy SELECT * FROM (...) */
+
+ if (push_select(wrapping_sel)) // for Items & TABLE_LIST
+ DBUG_RETURN(NULL);
+
+ /* add SELECT list*/
+ {
+ Item *item= new (thd->mem_root) Item_field(thd, context, star_clex_str);
+ if (item == NULL)
+ goto err;
+ if (add_item_to_list(thd, item))
+ goto err;
+ (wrapping_sel->with_wild)++;
+ }
+
+ unit->first_select()->set_linkage(DERIVED_TABLE_TYPE);
+
+ ti= new (thd->mem_root) Table_ident(unit);
+ if (ti == NULL)
+ goto err;
+ {
+ TABLE_LIST *table_list;
+ LEX_CSTRING alias;
+ if (wrapping_sel->make_unique_derived_name(thd, &alias))
+ goto err;
+
+ if (!(table_list= wrapping_sel->add_table_to_list(thd, ti, &alias,
+ 0, TL_READ,
+ MDL_SHARED_READ)))
+ goto err;
+
+ context->resolve_in_table_list_only(table_list);
+ wrapping_sel->add_joined_table(table_list);
+ }
+
+ pop_select();
+
+ derived_tables|= DERIVED_SUBQUERY;
+
+ DBUG_RETURN(wrapping_sel);
+
+err:
+ pop_select();
+ DBUG_RETURN(NULL);
+}
+
+SELECT_LEX *LEX::wrap_select_chain_into_derived(SELECT_LEX *sel)
+{
+ SELECT_LEX *dummy_select;
+ SELECT_LEX_UNIT *unit;
+ Table_ident *ti;
+ DBUG_ENTER("LEX::wrap_select_chain_into_derived");
+
+ if (!(dummy_select= alloc_select(TRUE)))
+ DBUG_RETURN(NULL);
+ Name_resolution_context *context= &dummy_select->context;
+ dummy_select->automatic_brackets= FALSE;
+ sel->distinct= TRUE; // First select has not this attribute (safety)
+
+ if (!(unit= dummy_select->attach_selects_chain(sel, context)))
+ DBUG_RETURN(NULL);
+
+ /* stuff dummy SELECT * FROM (...) */
+
+ if (push_select(dummy_select)) // for Items & TABLE_LIST
+ DBUG_RETURN(NULL);
+
+ /* add SELECT list*/
+ {
+ Item *item= new (thd->mem_root) Item_field(thd, context, star_clex_str);
+ if (item == NULL)
+ goto err;
+ if (add_item_to_list(thd, item))
+ goto err;
+ (dummy_select->with_wild)++;
+ }
+
+ sel->set_linkage(DERIVED_TABLE_TYPE);
+
+ ti= new (thd->mem_root) Table_ident(unit);
+ if (ti == NULL)
+ goto err;
+ {
+ TABLE_LIST *table_list;
+ LEX_CSTRING alias;
+ if (dummy_select->make_unique_derived_name(thd, &alias))
+ goto err;
+
+ if (!(table_list= dummy_select->add_table_to_list(thd, ti, &alias,
+ 0, TL_READ,
+ MDL_SHARED_READ)))
+ goto err;
+
+ context->resolve_in_table_list_only(table_list);
+ dummy_select->add_joined_table(table_list);
+ }
+
+ pop_select();
+
+ derived_tables|= DERIVED_SUBQUERY;
+
+ DBUG_RETURN(dummy_select);
+
+err:
+ pop_select();
+ DBUG_RETURN(NULL);
+}
+
+bool LEX::push_context(Name_resolution_context *context)
+{
+ DBUG_ENTER("LEX::push_context");
+ DBUG_PRINT("info", ("Context: %p Select: %p (%d)",
+ context, context->select_lex,
+ (context->select_lex ?
+ context->select_lex->select_number:
+ 0)));
+ bool res= context_stack.push_front(context, thd->mem_root);
+ DBUG_RETURN(res);
+}
+
+
+Name_resolution_context *LEX::pop_context()
+{
+ DBUG_ENTER("LEX::pop_context");
+ Name_resolution_context *context= context_stack.pop();
+ DBUG_PRINT("info", ("Context: %p Select: %p (%d)",
+ context, context->select_lex,
+ (context->select_lex ?
+ context->select_lex->select_number:
+ 0)));
+ DBUG_RETURN(context);
+}
+
+
+SELECT_LEX *LEX::create_priority_nest(SELECT_LEX *first_in_nest)
+{
+ DBUG_ENTER("LEX::create_priority_nest");
+ DBUG_ASSERT(first_in_nest->first_nested);
+ enum sub_select_type wr_unit_type= first_in_nest->get_linkage();
+ bool wr_distinct= first_in_nest->distinct;
+ SELECT_LEX *attach_to= first_in_nest->first_nested;
+ attach_to->cut_next();
+ SELECT_LEX *wrapper= wrap_select_chain_into_derived(first_in_nest);
+ if (wrapper)
+ {
+ first_in_nest->first_nested= NULL;
+ wrapper->set_linkage_and_distinct(wr_unit_type, wr_distinct);
+ wrapper->first_nested= attach_to->first_nested;
+ wrapper->set_master_unit(attach_to->master_unit());
+ attach_to->link_neighbour(wrapper);
+ }
+ DBUG_RETURN(wrapper);
+}
+
+
+/**
+ Checks if we need finish "automatic brackets" mode
+
+ INTERSECT has higher priority then UNION and EXCEPT, so when it is need we
+ automatically create lower layer for INTERSECT (automatic brackets) and
+ here we check if we should return back one level up during parsing procedure.
+*/
+
+void LEX::check_automatic_up(enum sub_select_type type)
+{
+ if (type != INTERSECT_TYPE &&
+ current_select->get_linkage() == INTERSECT_TYPE &&
+ current_select->outer_select() &&
+ current_select->outer_select()->automatic_brackets)
+ {
+ nest_level--;
+ current_select= current_select->outer_select();
+ }
+}
+
+
+sp_variable *LEX::sp_param_init(LEX_CSTRING *name)
+{
+ if (spcont->find_variable(name, true))
+ {
+ my_error(ER_SP_DUP_PARAM, MYF(0), name->str);
+ return NULL;
+ }
+ sp_variable *spvar= spcont->add_variable(thd, name);
+ init_last_field(&spvar->field_def, name,
+ thd->variables.collation_database);
+ return spvar;
+}
+
+
+bool LEX::sp_param_fill_definition(sp_variable *spvar,
+ const Lex_field_type_st &def)
+{
+ return
+ last_field->set_attributes(thd, def, charset,
+ COLUMN_DEFINITION_ROUTINE_PARAM) ||
+ sphead->fill_spvar_definition(thd, last_field, &spvar->name);
+}
+
+
+bool LEX::sf_return_fill_definition(const Lex_field_type_st &def)
+{
+ return
+ last_field->set_attributes(thd, def, charset,
+ COLUMN_DEFINITION_FUNCTION_RETURN) ||
+ sphead->fill_field_definition(thd, last_field);
+}
+
+
+void LEX::set_stmt_init()
+{
+ sql_command= SQLCOM_SET_OPTION;
+ mysql_init_select(this);
+ option_type= OPT_SESSION;
+ autocommit= 0;
+ var_list.empty();
+};
+
+
+/**
+ Find a local or a package body variable by name.
+ @param IN name - the variable name
+ @param OUT ctx - NULL, if the variable was not found,
+ or LEX::spcont (if a local variable was found)
+ or the package top level context
+ (if a package variable was found)
+ @param OUT handler - NULL, if the variable was not found,
+ or a pointer to rcontext handler
+ @retval - the variable (if found), or NULL otherwise.
+*/
+sp_variable *
+LEX::find_variable(const LEX_CSTRING *name,
+ sp_pcontext **ctx,
+ const Sp_rcontext_handler **rh) const
+{
+ sp_variable *spv;
+ if (spcont && (spv= spcont->find_variable(name, false)))
+ {
+ *ctx= spcont;
+ *rh= &sp_rcontext_handler_local;
+ return spv;
+ }
+ sp_package *pkg= sphead ? sphead->m_parent : NULL;
+ if (pkg && (spv= pkg->find_package_variable(name)))
+ {
+ *ctx= pkg->get_parse_context()->child_context(0);
+ *rh= &sp_rcontext_handler_package_body;
+ return spv;
+ }
+ *ctx= NULL;
+ *rh= NULL;
+ return NULL;
+}
+
+
+static bool is_new(const char *str)
+{
+ return (str[0] == 'n' || str[0] == 'N') &&
+ (str[1] == 'e' || str[1] == 'E') &&
+ (str[2] == 'w' || str[2] == 'W');
+}
+
+static bool is_old(const char *str)
+{
+ return (str[0] == 'o' || str[0] == 'O') &&
+ (str[1] == 'l' || str[1] == 'L') &&
+ (str[2] == 'd' || str[2] == 'D');
+}
+
+
+bool LEX::is_trigger_new_or_old_reference(const LEX_CSTRING *name) const
+{
+ // "name" is not necessarily NULL-terminated!
+ return sphead && sphead->m_handler->type() == SP_TYPE_TRIGGER &&
+ name->length == 3 && (is_new(name->str) || is_old(name->str));
+}
+
+
+void LEX::sp_variable_declarations_init(THD *thd, int nvars)
+{
+ sp_variable *spvar= spcont->get_last_context_variable();
+
+ sphead->reset_lex(thd);
+ spcont->declare_var_boundary(nvars);
+ thd->lex->init_last_field(&spvar->field_def, &spvar->name,
+ thd->variables.collation_database);
+}
+
+
+bool LEX::sp_variable_declarations_set_default(THD *thd, int nvars,
+ Item *dflt_value_item)
+{
+ bool has_default_clause= dflt_value_item != NULL;
+ if (!has_default_clause &&
+ unlikely(!(dflt_value_item= new (thd->mem_root) Item_null(thd))))
+ return true;
+
+ sp_variable *first_spvar = NULL;
+
+ for (uint i= 0 ; i < (uint) nvars ; i++)
+ {
+ sp_variable *spvar= spcont->get_last_context_variable((uint) nvars - 1 - i);
+
+ if (i == 0) {
+ first_spvar = spvar;
+ } else if (has_default_clause) {
+ Item_splocal *item =
+ new (thd->mem_root)
+ Item_splocal(thd, &sp_rcontext_handler_local,
+ &first_spvar->name, first_spvar->offset,
+ first_spvar->type_handler(), 0, 0);
+ if (item == NULL)
+ return true; // OOM
+#ifndef DBUG_OFF
+ item->m_sp = sphead;
+#endif
+ dflt_value_item = item;
+ }
+
+ bool last= i + 1 == (uint) nvars;
+ spvar->default_value= dflt_value_item;
+ /* The last instruction is responsible for freeing LEX. */
+ sp_instr_set *is= new (thd->mem_root)
+ sp_instr_set(sphead->instructions(),
+ spcont, &sp_rcontext_handler_local,
+ spvar->offset, dflt_value_item,
+ this, last);
+ if (unlikely(is == NULL || sphead->add_instr(is)))
+ return true;
+ }
+ return false;
+}
+
+
+bool
+LEX::sp_variable_declarations_copy_type_finalize(THD *thd, int nvars,
+ const Column_definition &ref,
+ Row_definition_list *fields,
+ Item *default_value)
+{
+ for (uint i= 0 ; i < (uint) nvars; i++)
+ {
+ sp_variable *spvar= spcont->get_last_context_variable((uint) nvars - 1 - i);
+ spvar->field_def.set_type(ref);
+ if (fields)
+ {
+ DBUG_ASSERT(ref.type_handler() == &type_handler_row);
+ spvar->field_def.set_row_field_definitions(fields);
+ }
+ spvar->field_def.field_name= spvar->name;
+ }
+ if (unlikely(sp_variable_declarations_set_default(thd, nvars,
+ default_value)))
+ return true;
+ spcont->declare_var_boundary(0);
+ return sphead->restore_lex(thd);
+}
+
+
+bool LEX::sp_variable_declarations_finalize(THD *thd, int nvars,
+ const Column_definition *cdef,
+ Item *dflt_value_item)
+{
+ DBUG_ASSERT(cdef);
+ Column_definition tmp(*cdef);
+ if (sphead->fill_spvar_definition(thd, &tmp))
+ return true;
+ return sp_variable_declarations_copy_type_finalize(thd, nvars, tmp, NULL,
+ dflt_value_item);
+}
+
+
+bool LEX::sp_variable_declarations_row_finalize(THD *thd, int nvars,
+ Row_definition_list *row,
+ Item *dflt_value_item)
+{
+ DBUG_ASSERT(row);
+ /*
+ Prepare all row fields.
+ Note, we do it only one time outside of the below loop.
+ The converted list in "row" is further reused by all variable
+ declarations processed by the current call.
+ Example:
+ DECLARE
+ a, b, c ROW(x VARCHAR(10) CHARACTER SET utf8);
+ BEGIN
+ ...
+ END;
+ */
+ if (sphead->row_fill_field_definitions(thd, row))
+ return true;
+
+ for (uint i= 0 ; i < (uint) nvars ; i++)
+ {
+ sp_variable *spvar= spcont->get_last_context_variable((uint) nvars - 1 - i);
+ spvar->field_def.set_row_field_definitions(row);
+ if (sphead->fill_spvar_definition(thd, &spvar->field_def, &spvar->name))
+ return true;
+ }
+
+ if (sp_variable_declarations_set_default(thd, nvars, dflt_value_item))
+ return true;
+ spcont->declare_var_boundary(0);
+ return sphead->restore_lex(thd);
+}
+
+
+/**
+ Finalize a %ROWTYPE declaration, e.g.:
+ DECLARE a,b,c,d t1%ROWTYPE := ROW(1,2,3);
+
+ @param thd - the current thd
+ @param nvars - the number of variables in the declaration
+ @param ref - the table or cursor name (see comments below)
+ @param def - the default value, e.g., ROW(1,2,3), or NULL (no default).
+*/
+bool
+LEX::sp_variable_declarations_rowtype_finalize(THD *thd, int nvars,
+ Qualified_column_ident *ref,
+ Item *def)
+{
+ uint coffp;
+ const sp_pcursor *pcursor= ref->table.str && ref->db.str ? NULL :
+ spcont->find_cursor(&ref->m_column, &coffp,
+ false);
+ if (pcursor)
+ return sp_variable_declarations_cursor_rowtype_finalize(thd, nvars,
+ coffp, def);
+ /*
+ When parsing a qualified identifier chain, the parser does not know yet
+ if it's going to be a qualified column name (for %TYPE),
+ or a qualified table name (for %ROWTYPE). So it collects the chain
+ into Qualified_column_ident.
+ Now we know that it was actually a qualified table name (%ROWTYPE).
+ Create a new Table_ident from Qualified_column_ident,
+ shifting fields as follows:
+ - ref->m_column becomes table_ref->table
+ - ref->table becomes table_ref->db
+ */
+ return sp_variable_declarations_table_rowtype_finalize(thd, nvars,
+ ref->table,
+ ref->m_column,
+ def);
+}
+
+
+bool
+LEX::sp_variable_declarations_table_rowtype_finalize(THD *thd, int nvars,
+ const LEX_CSTRING &db,
+ const LEX_CSTRING &table,
+ Item *def)
+{
+ Table_ident *table_ref;
+ if (unlikely(!(table_ref=
+ new (thd->mem_root) Table_ident(thd, &db, &table, false))))
+ return true;
+ // Loop through all variables in the same declaration
+ for (uint i= 0 ; i < (uint) nvars; i++)
+ {
+ sp_variable *spvar= spcont->get_last_context_variable((uint) nvars - 1 - i);
+ spvar->field_def.set_table_rowtype_ref(table_ref);
+ sphead->fill_spvar_definition(thd, &spvar->field_def, &spvar->name);
+ }
+ if (sp_variable_declarations_set_default(thd, nvars, def))
+ return true;
+ // Make sure sp_rcontext is created using the invoker security context:
+ sphead->m_flags|= sp_head::HAS_COLUMN_TYPE_REFS;
+ spcont->declare_var_boundary(0);
+ return sphead->restore_lex(thd);
+}
+
+
+bool
+LEX::sp_variable_declarations_cursor_rowtype_finalize(THD *thd, int nvars,
+ uint offset,
+ Item *def)
+{
+ const sp_pcursor *pcursor= spcont->find_cursor(offset);
+
+ // Loop through all variables in the same declaration
+ for (uint i= 0 ; i < (uint) nvars; i++)
+ {
+ sp_variable *spvar= spcont->get_last_context_variable((uint) nvars - 1 - i);
+
+ spvar->field_def.set_cursor_rowtype_ref(offset);
+ sp_instr_cursor_copy_struct *instr=
+ new (thd->mem_root) sp_instr_cursor_copy_struct(sphead->instructions(),
+ spcont, offset,
+ pcursor->lex(),
+ spvar->offset);
+ if (instr == NULL || sphead->add_instr(instr))
+ return true;
+
+ sphead->fill_spvar_definition(thd, &spvar->field_def, &spvar->name);
+ }
+ if (unlikely(sp_variable_declarations_set_default(thd, nvars, def)))
+ return true;
+ // Make sure sp_rcontext is created using the invoker security context:
+ sphead->m_flags|= sp_head::HAS_COLUMN_TYPE_REFS;
+ spcont->declare_var_boundary(0);
+ return sphead->restore_lex(thd);
+}
+
+
+/*
+ Add declarations for table column and SP variable anchor types:
+ - DECLARE spvar1 TYPE OF db1.table1.column1;
+ - DECLARE spvar1 TYPE OF table1.column1;
+ - DECLARE spvar1 TYPE OF spvar0;
+*/
+bool
+LEX::sp_variable_declarations_with_ref_finalize(THD *thd, int nvars,
+ Qualified_column_ident *ref,
+ Item *def)
+{
+ return ref->db.length == 0 && ref->table.length == 0 ?
+ sp_variable_declarations_vartype_finalize(thd, nvars, ref->m_column, def) :
+ sp_variable_declarations_column_type_finalize(thd, nvars, ref, def);
+}
+
+
+bool
+LEX::sp_variable_declarations_column_type_finalize(THD *thd, int nvars,
+ Qualified_column_ident *ref,
+ Item *def)
+{
+ for (uint i= 0 ; i < (uint) nvars; i++)
+ {
+ sp_variable *spvar= spcont->get_last_context_variable((uint) nvars - 1 - i);
+ spvar->field_def.set_column_type_ref(ref);
+ spvar->field_def.field_name= spvar->name;
+ }
+ sphead->m_flags|= sp_head::HAS_COLUMN_TYPE_REFS;
+ if (sp_variable_declarations_set_default(thd, nvars, def))
+ return true;
+ spcont->declare_var_boundary(0);
+ return sphead->restore_lex(thd);
+}
+
+
+bool
+LEX::sp_variable_declarations_vartype_finalize(THD *thd, int nvars,
+ const LEX_CSTRING &ref,
+ Item *default_value)
+{
+ sp_variable *t;
+ if (!spcont || !(t= spcont->find_variable(&ref, false)))
+ {
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), ref.str);
+ return true;
+ }
+
+ if (t->field_def.is_cursor_rowtype_ref())
+ {
+ uint offset= t->field_def.cursor_rowtype_offset();
+ return sp_variable_declarations_cursor_rowtype_finalize(thd, nvars,
+ offset,
+ default_value);
+ }
+
+ if (t->field_def.is_column_type_ref())
+ {
+ Qualified_column_ident *tmp= t->field_def.column_type_ref();
+ return sp_variable_declarations_column_type_finalize(thd, nvars, tmp,
+ default_value);
+ }
+
+ if (t->field_def.is_table_rowtype_ref())
+ {
+ const Table_ident *tmp= t->field_def.table_rowtype_ref();
+ return sp_variable_declarations_table_rowtype_finalize(thd, nvars,
+ tmp->db,
+ tmp->table,
+ default_value);
+ }
+
+ // A reference to a scalar or a row variable with an explicit data type
+ return sp_variable_declarations_copy_type_finalize(thd, nvars,
+ t->field_def,
+ t->field_def.
+ row_field_definitions(),
+ default_value);
+}
+
+
+/**********************************************************************
+ The FOR LOOP statement
+
+ This syntax:
+ FOR i IN lower_bound .. upper_bound
+ LOOP
+ statements;
+ END LOOP;
+
+ is translated into:
+
+ DECLARE
+ i INT := lower_bound;
+ j INT := upper_bound;
+ BEGIN
+ WHILE i <= j
+ LOOP
+ statements;
+ i:= i + 1;
+ END LOOP;
+ END;
+*/
+
+
+sp_variable *LEX::sp_add_for_loop_variable(THD *thd, const LEX_CSTRING *name,
+ Item *value)
+{
+ sp_variable *spvar= spcont->add_variable(thd, name);
+ spcont->declare_var_boundary(1);
+ spvar->field_def.field_name= spvar->name;
+ spvar->field_def.set_handler(&type_handler_slonglong);
+ type_handler_slonglong.Column_definition_prepare_stage2(&spvar->field_def,
+ NULL, HA_CAN_GEOMETRY);
+ if (!value && unlikely(!(value= new (thd->mem_root) Item_null(thd))))
+ return NULL;
+
+ spvar->default_value= value;
+ sp_instr_set *is= new (thd->mem_root)
+ sp_instr_set(sphead->instructions(),
+ spcont, &sp_rcontext_handler_local,
+ spvar->offset, value,
+ this, true);
+ if (unlikely(is == NULL || sphead->add_instr(is)))
+ return NULL;
+ spcont->declare_var_boundary(0);
+ return spvar;
+}
+
+
+bool LEX::sp_for_loop_implicit_cursor_statement(THD *thd,
+ Lex_for_loop_bounds_st *bounds,
+ sp_lex_cursor *cur)
+{
+ Item *item;
+ DBUG_ASSERT(sphead);
+ LEX_CSTRING name= {STRING_WITH_LEN("[implicit_cursor]") };
+ if (sp_declare_cursor(thd, &name, cur, NULL, true))
+ return true;
+ DBUG_ASSERT(thd->lex == this);
+ if (unlikely(!(bounds->m_index=
+ new (thd->mem_root) sp_assignment_lex(thd, this))))
+ return true;
+ bounds->m_index->sp_lex_in_use= true;
+ sphead->reset_lex(thd, bounds->m_index);
+ DBUG_ASSERT(thd->lex != this);
+ /*
+ We pass NULL as Name_resolution_context here.
+ It's OK, fix_fields() will not be called for this Item_field created.
+ Item_field is only needed for LEX::sp_for_loop_cursor_declarations()
+ and is used to transfer the loop index variable name, "rec" in this example:
+ FOR rec IN (SELECT * FROM t1)
+ DO
+ SELECT rec.a, rec.b;
+ END FOR;
+ */
+ if (!(item= new (thd->mem_root) Item_field(thd, NULL, name)))
+ return true;
+ bounds->m_index->set_item_and_free_list(item, NULL);
+ if (thd->lex->sphead->restore_lex(thd))
+ return true;
+ DBUG_ASSERT(thd->lex == this);
+ bounds->m_direction= 1;
+ bounds->m_target_bound= NULL;
+ bounds->m_implicit_cursor= true;
+ return false;
+}
+
+sp_variable *
+LEX::sp_add_for_loop_cursor_variable(THD *thd,
+ const LEX_CSTRING *name,
+ const sp_pcursor *pcursor,
+ uint coffset,
+ sp_assignment_lex *param_lex,
+ Item_args *parameters)
+{
+ sp_variable *spvar= spcont->add_variable(thd, name);
+ if (!spvar)
+ return NULL;
+ spcont->declare_var_boundary(1);
+ sphead->fill_spvar_definition(thd, &spvar->field_def, &spvar->name);
+ if (unlikely(!(spvar->default_value= new (thd->mem_root) Item_null(thd))))
+ return NULL;
+
+ spvar->field_def.set_cursor_rowtype_ref(coffset);
+
+ if (unlikely(sphead->add_for_loop_open_cursor(thd, spcont, spvar, pcursor,
+ coffset,
+ param_lex, parameters)))
+ return NULL;
+
+ spcont->declare_var_boundary(0);
+ return spvar;
+}
+
+
+/**
+ Generate a code for a FOR loop condition:
+ - Make Item_splocal for the FOR loop index variable
+ - Make Item_splocal for the FOR loop upper bound variable
+ - Make a comparison function item on top of these two variables
+*/
+bool LEX::sp_for_loop_condition(THD *thd, const Lex_for_loop_st &loop)
+{
+ Item_splocal *args[2];
+ for (uint i= 0 ; i < 2; i++)
+ {
+ sp_variable *src= i == 0 ? loop.m_index : loop.m_target_bound;
+ args[i]= new (thd->mem_root)
+ Item_splocal(thd, &sp_rcontext_handler_local,
+ &src->name, src->offset, src->type_handler());
+ if (unlikely(args[i] == NULL))
+ return true;
+#ifdef DBUG_ASSERT_EXISTS
+ args[i]->m_sp= sphead;
+#endif
+ }
+
+ Item *expr= loop.m_direction > 0 ?
+ (Item *) new (thd->mem_root) Item_func_le(thd, args[0], args[1]) :
+ (Item *) new (thd->mem_root) Item_func_ge(thd, args[0], args[1]);
+ return unlikely(!expr) || unlikely(sp_while_loop_expression(thd, expr));
+}
+
+
+/**
+ Generate the FOR LOOP condition code in its own lex
+*/
+bool LEX::sp_for_loop_intrange_condition_test(THD *thd,
+ const Lex_for_loop_st &loop)
+{
+ spcont->set_for_loop(loop);
+ sphead->reset_lex(thd);
+ if (unlikely(thd->lex->sp_for_loop_condition(thd, loop)))
+ return true;
+ return thd->lex->sphead->restore_lex(thd);
+}
+
+
+bool LEX::sp_for_loop_cursor_condition_test(THD *thd,
+ const Lex_for_loop_st &loop)
+{
+ const LEX_CSTRING *cursor_name;
+ Item *expr;
+ spcont->set_for_loop(loop);
+ sphead->reset_lex(thd);
+ cursor_name= spcont->find_cursor(loop.m_cursor_offset);
+ DBUG_ASSERT(cursor_name);
+ if (unlikely(!(expr=
+ new (thd->mem_root)
+ Item_func_cursor_found(thd, cursor_name,
+ loop.m_cursor_offset))))
+ return true;
+ if (thd->lex->sp_while_loop_expression(thd, expr))
+ return true;
+ return thd->lex->sphead->restore_lex(thd);
+}
+
+
+bool LEX::sp_for_loop_intrange_declarations(THD *thd, Lex_for_loop_st *loop,
+ const LEX_CSTRING *index,
+ const Lex_for_loop_bounds_st &bounds)
+{
+ Item *item;
+ if ((item= bounds.m_index->get_item())->type() == Item::FIELD_ITEM)
+ {
+ // We're here is the lower bound is unknown identifier
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), item->full_name());
+ return true;
+ }
+ if ((item= bounds.m_target_bound->get_item())->type() == Item::FIELD_ITEM)
+ {
+ // We're here is the upper bound is unknown identifier
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), item->full_name());
+ return true;
+ }
+ if (!(loop->m_index=
+ bounds.m_index->sp_add_for_loop_variable(thd, index,
+ bounds.m_index->get_item())))
+ return true;
+ if (unlikely(!(loop->m_target_bound=
+ bounds.m_target_bound->
+ sp_add_for_loop_target_bound(thd,
+ bounds.
+ m_target_bound->get_item()))))
+ return true;
+ loop->m_direction= bounds.m_direction;
+ loop->m_implicit_cursor= 0;
+ return false;
+}
+
+
+bool LEX::sp_for_loop_cursor_declarations(THD *thd,
+ Lex_for_loop_st *loop,
+ const LEX_CSTRING *index,
+ const Lex_for_loop_bounds_st &bounds)
+{
+ Item *item= bounds.m_index->get_item();
+ Item_splocal *item_splocal;
+ Item_field *item_field;
+ Item_func_sp *item_func_sp= NULL;
+ LEX_CSTRING name;
+ uint coffs, param_count= 0;
+ const sp_pcursor *pcursor;
+ DBUG_ENTER("LEX::sp_for_loop_cursor_declarations");
+
+ if ((item_splocal= item->get_item_splocal()))
+ name= item_splocal->m_name;
+ else if ((item_field= item->type() == Item::FIELD_ITEM ?
+ static_cast<Item_field *>(item) : NULL) &&
+ item_field->table_name.str == NULL)
+ name= item_field->field_name;
+ else if (item->type() == Item::FUNC_ITEM &&
+ static_cast<Item_func*>(item)->functype() == Item_func::FUNC_SP &&
+ !static_cast<Item_func_sp*>(item)->get_sp_name()->m_explicit_name)
+ {
+ /*
+ When a FOR LOOP for a cursor with parameters is parsed:
+ FOR index IN cursor(1,2,3) LOOP
+ statements;
+ END LOOP;
+ the parser scans "cursor(1,2,3)" using the "expr" rule,
+ so it thinks that cursor(1,2,3) is a stored function call.
+ It's not easy to implement this without using "expr" because
+ of grammar conflicts.
+ As a side effect, the Item_func_sp and its arguments in the parentheses
+ belong to the same LEX. This is different from an explicit
+ "OPEN cursor(1,2,3)" where every expression belongs to a separate LEX.
+ */
+ item_func_sp= static_cast<Item_func_sp*>(item);
+ name= item_func_sp->get_sp_name()->m_name;
+ param_count= item_func_sp->argument_count();
+ }
+ else
+ {
+ thd->parse_error();
+ DBUG_RETURN(true);
+ }
+ if (unlikely(!(pcursor= spcont->find_cursor_with_error(&name, &coffs,
+ false)) ||
+ pcursor->check_param_count_with_error(param_count)))
+ DBUG_RETURN(true);
+
+ if (!(loop->m_index= sp_add_for_loop_cursor_variable(thd, index,
+ pcursor, coffs,
+ bounds.m_index,
+ item_func_sp)))
+ DBUG_RETURN(true);
+ loop->m_target_bound= NULL;
+ loop->m_direction= bounds.m_direction;
+ loop->m_cursor_offset= coffs;
+ loop->m_implicit_cursor= bounds.m_implicit_cursor;
+ DBUG_RETURN(false);
+}
+
+
+/**
+ Generate a code for a FOR loop index increment
+*/
+bool LEX::sp_for_loop_increment(THD *thd, const Lex_for_loop_st &loop)
+{
+ Item_splocal *splocal= new (thd->mem_root)
+ Item_splocal(thd, &sp_rcontext_handler_local,
+ &loop.m_index->name, loop.m_index->offset,
+ loop.m_index->type_handler());
+ if (unlikely(splocal == NULL))
+ return true;
+#ifdef DBUG_ASSERT_EXISTS
+ splocal->m_sp= sphead;
+#endif
+ Item_int *inc= new (thd->mem_root) Item_int(thd, loop.m_direction);
+ if (unlikely(!inc))
+ return true;
+ Item *expr= new (thd->mem_root) Item_func_plus(thd, splocal, inc);
+ if (unlikely(!expr) ||
+ unlikely(sphead->set_local_variable(thd, spcont,
+ &sp_rcontext_handler_local,
+ loop.m_index, expr, this, true)))
+ return true;
+ return false;
+}
+
+
+bool LEX::sp_for_loop_intrange_finalize(THD *thd, const Lex_for_loop_st &loop)
+{
+ sphead->reset_lex(thd);
+
+ // Generate FOR LOOP index increment in its own lex
+ DBUG_ASSERT(this != thd->lex);
+ if (unlikely(thd->lex->sp_for_loop_increment(thd, loop) ||
+ thd->lex->sphead->restore_lex(thd)))
+ return true;
+
+ // Generate a jump to the beginning of the loop
+ DBUG_ASSERT(this == thd->lex);
+ return sp_while_loop_finalize(thd);
+}
+
+
+bool LEX::sp_for_loop_cursor_finalize(THD *thd, const Lex_for_loop_st &loop)
+{
+ sp_instr_cfetch *instr=
+ new (thd->mem_root) sp_instr_cfetch(sphead->instructions(),
+ spcont, loop.m_cursor_offset, false);
+ if (unlikely(instr == NULL) || unlikely(sphead->add_instr(instr)))
+ return true;
+ instr->add_to_varlist(loop.m_index);
+ // Generate a jump to the beginning of the loop
+ return sp_while_loop_finalize(thd);
+}
+
+bool LEX::sp_for_loop_outer_block_finalize(THD *thd,
+ const Lex_for_loop_st &loop)
+{
+ Lex_spblock tmp;
+ tmp.curs= MY_TEST(loop.m_implicit_cursor);
+ if (unlikely(sp_block_finalize(thd, tmp))) // The outer DECLARE..BEGIN..END
+ return true;
+ if (!loop.is_for_loop_explicit_cursor())
+ return false;
+ /*
+ Explicit cursor FOR loop must close the cursor automatically.
+ Note, implicit cursor FOR loop does not need to close the cursor,
+ it's closed by sp_instr_cpop.
+ */
+ sp_instr_cclose *ic= new (thd->mem_root)
+ sp_instr_cclose(sphead->instructions(), spcont,
+ loop.m_cursor_offset);
+ return ic == NULL || sphead->add_instr(ic);
+}
+
+/***************************************************************************/
+
+bool LEX::sp_declare_cursor(THD *thd, const LEX_CSTRING *name,
+ sp_lex_cursor *cursor_stmt,
+ sp_pcontext *param_ctx, bool add_cpush_instr)
+{
+ uint offp;
+ sp_instr_cpush *i;
+
+ if (spcont->find_cursor(name, &offp, true))
+ {
+ my_error(ER_SP_DUP_CURS, MYF(0), name->str);
+ return true;
+ }
+
+ if (unlikely(spcont->add_cursor(name, param_ctx, cursor_stmt)))
+ return true;
+
+ if (add_cpush_instr)
+ {
+ i= new (thd->mem_root)
+ sp_instr_cpush(sphead->instructions(), spcont, cursor_stmt,
+ spcont->current_cursor_count() - 1);
+ return unlikely(i == NULL) || unlikely(sphead->add_instr(i));
+ }
+ return false;
+}
+
+
+/**
+ Generate an SP code for an "OPEN cursor_name" statement.
+ @param thd
+ @param name - Name of the cursor
+ @param parameters - Cursor parameters, e.g. OPEN c(1,2,3)
+ @returns - false on success, true on error
+*/
+bool LEX::sp_open_cursor(THD *thd, const LEX_CSTRING *name,
+ List<sp_assignment_lex> *parameters)
+{
+ uint offset;
+ const sp_pcursor *pcursor;
+ uint param_count= parameters ? parameters->elements : 0;
+ return !(pcursor= spcont->find_cursor_with_error(name, &offset, false)) ||
+ pcursor->check_param_count_with_error(param_count) ||
+ sphead->add_open_cursor(thd, spcont, offset,
+ pcursor->param_context(), parameters);
+}
+
+
+bool LEX::sp_handler_declaration_init(THD *thd, int type)
+{
+ sp_handler *h= spcont->add_handler(thd, (sp_handler::enum_type) type);
+
+ spcont= spcont->push_context(thd, sp_pcontext::HANDLER_SCOPE);
+
+ sp_instr_hpush_jump *i=
+ new (thd->mem_root) sp_instr_hpush_jump(sphead->instructions(), spcont, h);
+
+ if (unlikely(i == NULL) || unlikely(sphead->add_instr(i)))
+ return true;
+
+ /* For continue handlers, mark end of handler scope. */
+ if (type == sp_handler::CONTINUE &&
+ unlikely(sphead->push_backpatch(thd, i, spcont->last_label())))
+ return true;
+
+ if (unlikely(sphead->push_backpatch(thd, i,
+ spcont->push_label(thd, &empty_clex_str,
+ 0))))
+ return true;
+
+ return false;
+}
+
+
+bool LEX::sp_handler_declaration_finalize(THD *thd, int type)
+{
+ sp_label *hlab= spcont->pop_label(); /* After this hdlr */
+ sp_instr_hreturn *i;
+
+ if (type == sp_handler::CONTINUE)
+ {
+ i= new (thd->mem_root) sp_instr_hreturn(sphead->instructions(), spcont);
+ if (unlikely(i == NULL) ||
+ unlikely(sphead->add_instr(i)))
+ return true;
+ }
+ else
+ { /* EXIT or UNDO handler, just jump to the end of the block */
+ i= new (thd->mem_root) sp_instr_hreturn(sphead->instructions(), spcont);
+ if (unlikely(i == NULL) ||
+ unlikely(sphead->add_instr(i)) ||
+ unlikely(sphead->push_backpatch(thd, i, spcont->last_label()))) /* Block end */
+ return true;
+ }
+ sphead->backpatch(hlab);
+ spcont= spcont->pop_context();
+ return false;
+}
+
+
+void LEX::sp_block_init(THD *thd, const LEX_CSTRING *label)
+{
+ spcont->push_label(thd, label, sphead->instructions(), sp_label::BEGIN);
+ spcont= spcont->push_context(thd, sp_pcontext::REGULAR_SCOPE);
+}
+
+
+bool LEX::sp_block_finalize(THD *thd, const Lex_spblock_st spblock,
+ class sp_label **splabel)
+{
+ sp_head *sp= sphead;
+ sp_pcontext *ctx= spcont;
+ sp_instr *i;
+
+ sp->backpatch(ctx->last_label()); /* We always have a label */
+ if (spblock.hndlrs)
+ {
+ i= new (thd->mem_root)
+ sp_instr_hpop(sp->instructions(), ctx, spblock.hndlrs);
+ if (unlikely(i == NULL) ||
+ unlikely(sp->add_instr(i)))
+ return true;
+ }
+ if (spblock.curs)
+ {
+ i= new (thd->mem_root)
+ sp_instr_cpop(sp->instructions(), ctx, spblock.curs);
+ if (unlikely(i == NULL) ||
+ unlikely(sp->add_instr(i)))
+ return true;
+ }
+ spcont= ctx->pop_context();
+ *splabel= spcont->pop_label();
+ return false;
+}
+
+
+bool LEX::sp_block_finalize(THD *thd, const Lex_spblock_st spblock,
+ const LEX_CSTRING *end_label)
+{
+ sp_label *splabel;
+ if (unlikely(sp_block_finalize(thd, spblock, &splabel)))
+ return true;
+ if (unlikely(end_label->str &&
+ lex_string_cmp(system_charset_info,
+ end_label, &splabel->name) != 0))
+ {
+ my_error(ER_SP_LABEL_MISMATCH, MYF(0), end_label->str);
+ return true;
+ }
+ return false;
+}
+
+
+sp_name *LEX::make_sp_name(THD *thd, const LEX_CSTRING *name)
+{
+ sp_name *res;
+ LEX_CSTRING db;
+ if (unlikely(check_routine_name(name)) ||
+ unlikely(copy_db_to(&db)) ||
+ unlikely((!(res= new (thd->mem_root) sp_name(&db, name, false)))))
+ return NULL;
+ return res;
+}
+
+
+/**
+ When a package routine name is stored in memory in Database_qualified_name,
+ the dot character is used to delimit package name from the routine name,
+ e.g.:
+ m_db= 'test'; -- database 'test'
+ m_name= 'p1.p1'; -- package 'p1', routine 'p1'
+ See database_qualified_name::make_package_routine_name() for details.
+ Disallow package routine names with dots,
+ to avoid ambiguity when interpreting m_name='p1.p1.p1', between:
+ a. package 'p1.p1' + routine 'p1'
+ b. package 'p1' + routine 'p1.p1'
+ m_name='p1.p1.p1' will always mean (a).
+*/
+sp_name *LEX::make_sp_name_package_routine(THD *thd, const LEX_CSTRING *name)
+{
+ sp_name *res= make_sp_name(thd, name);
+ if (likely(res) && unlikely(strchr(res->m_name.str, '.')))
+ {
+ my_error(ER_SP_WRONG_NAME, MYF(0), res->m_name.str);
+ res= NULL;
+ }
+ return res;
+}
+
+
+sp_name *LEX::make_sp_name(THD *thd, const LEX_CSTRING *name1,
+ const LEX_CSTRING *name2)
+{
+ sp_name *res;
+ LEX_CSTRING norm_name1;
+ if (unlikely(!name1->str) ||
+ unlikely(!thd->make_lex_string(&norm_name1, name1->str,
+ name1->length)) ||
+ unlikely(check_db_name((LEX_STRING *) &norm_name1)))
+ {
+ my_error(ER_WRONG_DB_NAME, MYF(0), name1->str);
+ return NULL;
+ }
+ if (unlikely(check_routine_name(name2)) ||
+ unlikely(!(res= new (thd->mem_root) sp_name(&norm_name1, name2, true))))
+ return NULL;
+ return res;
+}
+
+
+sp_head *LEX::make_sp_head(THD *thd, const sp_name *name,
+ const Sp_handler *sph,
+ enum_sp_aggregate_type agg_type)
+{
+ sp_package *package= get_sp_package();
+ sp_head *sp;
+
+ /* Order is important here: new - reset - init */
+ if (likely((sp= sp_head::create(package, sph, agg_type))))
+ {
+ sp->reset_thd_mem_root(thd);
+ sp->init(this);
+ if (name)
+ {
+ if (package)
+ sp->make_package_routine_name(sp->get_main_mem_root(),
+ package->m_db,
+ package->m_name,
+ name->m_name);
+ else
+ sp->init_sp_name(name);
+ sp->make_qname(sp->get_main_mem_root(), &sp->m_qname);
+ }
+ sphead= sp;
+ }
+ sp_chistics.init();
+ return sp;
+}
+
+
+sp_head *LEX::make_sp_head_no_recursive(THD *thd, const sp_name *name,
+ const Sp_handler *sph,
+ enum_sp_aggregate_type agg_type)
+{
+ sp_package *package= thd->lex->get_sp_package();
+ /*
+ Sp_handler::sp_clone_and_link_routine() generates a standalone-alike
+ statement to clone package routines for recursion, e.g.:
+ CREATE PROCEDURE p1 AS BEGIN NULL; END;
+ Translate a standalone routine handler to the corresponding
+ package routine handler if we're cloning a package routine, e.g.:
+ sp_handler_procedure -> sp_handler_package_procedure
+ sp_handler_function -> sp_handler_package_function
+ */
+ if (package && package->m_is_cloning_routine)
+ sph= sph->package_routine_handler();
+ if (!sphead ||
+ (package &&
+ (sph == &sp_handler_package_procedure ||
+ sph == &sp_handler_package_function)))
+ return make_sp_head(thd, name, sph, agg_type);
+ my_error(ER_SP_NO_RECURSIVE_CREATE, MYF(0), sph->type_str());
+ return NULL;
+}
+
+
+bool LEX::sp_body_finalize_routine(THD *thd)
+{
+ if (sphead->check_unresolved_goto())
+ return true;
+ sphead->set_stmt_end(thd);
+ sphead->restore_thd_mem_root(thd);
+ return false;
+}
+
+
+bool LEX::sp_body_finalize_procedure(THD *thd)
+{
+ return sphead->check_group_aggregate_instructions_forbid() ||
+ sp_body_finalize_routine(thd);
+}
+
+
+bool LEX::sp_body_finalize_procedure_standalone(THD *thd,
+ const sp_name *end_name)
+{
+ return sp_body_finalize_procedure(thd) ||
+ sphead->check_standalone_routine_end_name(end_name);
+}
+
+
+bool LEX::sp_body_finalize_function(THD *thd)
+{
+ if (sphead->is_not_allowed_in_function("function") ||
+ sphead->check_group_aggregate_instructions_function())
+ return true;
+ if (!(sphead->m_flags & sp_head::HAS_RETURN))
+ {
+ my_error(ER_SP_NORETURN, MYF(0), ErrConvDQName(sphead).ptr());
+ return true;
+ }
+ if (sp_body_finalize_routine(thd))
+ return true;
+ (void) is_native_function_with_warn(thd, &sphead->m_name);
+ return false;
+}
+
+
+bool LEX::sp_body_finalize_trigger(THD *thd)
+{
+ return sphead->is_not_allowed_in_function("trigger") ||
+ sp_body_finalize_procedure(thd);
+}
+
+
+bool LEX::sp_body_finalize_event(THD *thd)
+{
+ event_parse_data->body_changed= true;
+ return sp_body_finalize_procedure(thd);
+}
+
+
+bool LEX::stmt_create_stored_function_finalize_standalone(const sp_name *end_name)
+{
+ if (sphead->check_standalone_routine_end_name(end_name))
+ return true;
+ stmt_create_routine_finalize();
+ return false;
+}
+
+
+bool LEX::sp_block_with_exceptions_finalize_declarations(THD *thd)
+{
+ /*
+ [ DECLARE declarations ]
+ BEGIN executable_section
+ [ EXCEPTION exceptions ]
+ END
+
+ We are now at the "BEGIN" keyword.
+ We have collected all declarations, including DECLARE HANDLER directives.
+ But there will be possibly more handlers in the EXCEPTION section.
+
+ Generate a forward jump from the end of the DECLARE section to the
+ beginning of the EXCEPTION section, over the executable section.
+ */
+ return sphead->add_instr_jump(thd, spcont);
+}
+
+
+bool
+LEX::sp_block_with_exceptions_finalize_executable_section(THD *thd,
+ uint executable_section_ip)
+{
+ /*
+ We're now at the end of "executable_section" of the block,
+ near the "EXCEPTION" or the "END" keyword.
+ Generate a jump to the END of the block over the EXCEPTION section.
+ */
+ if (sphead->add_instr_jump_forward_with_backpatch(thd, spcont))
+ return true;
+ /*
+ Set the destination for the jump that we added in
+ sp_block_with_exceptions_finalize_declarations().
+ */
+ sp_instr *instr= sphead->get_instr(executable_section_ip - 1);
+ instr->backpatch(sphead->instructions(), spcont);
+ return false;
+}
+
+
+bool
+LEX::sp_block_with_exceptions_finalize_exceptions(THD *thd,
+ uint executable_section_ip,
+ uint exception_count)
+{
+ if (!exception_count)
+ {
+ /*
+ The jump from the end of DECLARE section to
+ the beginning of the EXCEPTION section that we added in
+ sp_block_with_exceptions_finalize_declarations() is useless
+ if there were no exceptions.
+ Replace it to "no operation".
+ */
+ return sphead->replace_instr_to_nop(thd, executable_section_ip - 1);
+ }
+ /*
+ Generate a jump from the end of the EXCEPTION code
+ to the executable section.
+ */
+ return sphead->add_instr_jump(thd, spcont, executable_section_ip);
+}
+
+
+bool LEX::sp_block_with_exceptions_add_empty(THD *thd)
+{
+ uint ip= sphead->instructions();
+ return sp_block_with_exceptions_finalize_executable_section(thd, ip) ||
+ sp_block_with_exceptions_finalize_exceptions(thd, ip, 0);
+}
+
+
+bool LEX::sp_change_context(THD *thd, const sp_pcontext *ctx, bool exclusive)
+{
+ uint n;
+ uint ip= sphead->instructions();
+ if ((n= spcont->diff_handlers(ctx, exclusive)))
+ {
+ sp_instr_hpop *hpop= new (thd->mem_root) sp_instr_hpop(ip++, spcont, n);
+ if (unlikely(hpop == NULL) || unlikely(sphead->add_instr(hpop)))
+ return true;
+ }
+ if ((n= spcont->diff_cursors(ctx, exclusive)))
+ {
+ sp_instr_cpop *cpop= new (thd->mem_root) sp_instr_cpop(ip++, spcont, n);
+ if (unlikely(cpop == NULL) || unlikely(sphead->add_instr(cpop)))
+ return true;
+ }
+ return false;
+}
+
+
+bool LEX::sp_leave_statement(THD *thd, const LEX_CSTRING *label_name)
+{
+ sp_label *lab= spcont->find_label(label_name);
+ if (unlikely(!lab))
+ {
+ my_error(ER_SP_LILABEL_MISMATCH, MYF(0), "LEAVE", label_name->str);
+ return true;
+ }
+ return sp_exit_block(thd, lab, NULL);
+}
+
+bool LEX::sp_goto_statement(THD *thd, const LEX_CSTRING *label_name)
+{
+ sp_label *lab= spcont->find_goto_label(label_name);
+ if (!lab || lab->ip == 0)
+ {
+ sp_label *delayedlabel;
+ if (!lab)
+ {
+ // Label not found --> add forward jump to an unknown label
+ spcont->push_goto_label(thd, label_name, 0, sp_label::GOTO);
+ delayedlabel= spcont->last_goto_label();
+ }
+ else
+ {
+ delayedlabel= lab;
+ }
+ return sphead->push_backpatch_goto(thd, spcont, delayedlabel);
+ }
+ else
+ {
+ // Label found (backward goto)
+ return sp_change_context(thd, lab->ctx, false) ||
+ sphead->add_instr_jump(thd, spcont, lab->ip); /* Jump back */
+ }
+ return false;
+}
+
+bool LEX::sp_push_goto_label(THD *thd, const LEX_CSTRING *label_name)
+{
+ sp_label *lab= spcont->find_goto_label(label_name, false);
+ if (lab)
+ {
+ if (unlikely(lab->ip != 0))
+ {
+ my_error(ER_SP_LABEL_REDEFINE, MYF(0), label_name->str);
+ return true;
+ }
+ lab->ip= sphead->instructions();
+
+ sp_label *beginblocklabel= spcont->find_label(&empty_clex_str);
+ sphead->backpatch_goto(thd, lab, beginblocklabel);
+ }
+ else
+ {
+ spcont->push_goto_label(thd, label_name, sphead->instructions());
+ }
+ return false;
+}
+
+bool LEX::sp_exit_block(THD *thd, sp_label *lab)
+{
+ /*
+ When jumping to a BEGIN-END block end, the target jump
+ points to the block hpop/cpop cleanup instructions,
+ so we should exclude the block context here.
+ When jumping to something else (i.e., SP_LAB_ITER),
+ there are no hpop/cpop at the jump destination,
+ so we should include the block context here for cleanup.
+ */
+ bool exclusive= (lab->type == sp_label::BEGIN);
+ return sp_change_context(thd, lab->ctx, exclusive) ||
+ sphead->add_instr_jump_forward_with_backpatch(thd, spcont, lab);
+}
+
+
+bool LEX::sp_exit_block(THD *thd, sp_label *lab, Item *when)
+{
+ if (!when)
+ return sp_exit_block(thd, lab);
+
+ DBUG_ASSERT(sphead == thd->lex->sphead);
+ DBUG_ASSERT(spcont == thd->lex->spcont);
+ sp_instr_jump_if_not *i= new (thd->mem_root)
+ sp_instr_jump_if_not(sphead->instructions(),
+ spcont,
+ when, this);
+ if (unlikely(i == NULL) ||
+ unlikely(sphead->add_instr(i)) ||
+ unlikely(sp_exit_block(thd, lab)))
+ return true;
+ i->backpatch(sphead->instructions(), spcont);
+ return false;
+}
+
+
+bool LEX::sp_exit_statement(THD *thd, Item *item)
+{
+ sp_label *lab= spcont->find_label_current_loop_start();
+ if (unlikely(!lab))
+ {
+ my_error(ER_SP_LILABEL_MISMATCH, MYF(0), "EXIT", "");
+ return true;
+ }
+ DBUG_ASSERT(lab->type == sp_label::ITERATION);
+ return sp_exit_block(thd, lab, item);
+}
+
+
+bool LEX::sp_exit_statement(THD *thd, const LEX_CSTRING *label_name, Item *item)
+{
+ sp_label *lab= spcont->find_label(label_name);
+ if (unlikely(!lab || lab->type != sp_label::ITERATION))
+ {
+ my_error(ER_SP_LILABEL_MISMATCH, MYF(0), "EXIT", label_name->str);
+ return true;
+ }
+ return sp_exit_block(thd, lab, item);
+}
+
+
+bool LEX::sp_iterate_statement(THD *thd, const LEX_CSTRING *label_name)
+{
+ sp_label *lab= spcont->find_label(label_name);
+ if (unlikely(!lab || lab->type != sp_label::ITERATION))
+ {
+ my_error(ER_SP_LILABEL_MISMATCH, MYF(0), "ITERATE", label_name->str);
+ return true;
+ }
+ return sp_continue_loop(thd, lab);
+}
+
+
+bool LEX::sp_continue_loop(THD *thd, sp_label *lab)
+{
+ if (lab->ctx->for_loop().m_index)
+ {
+ // We're in a FOR loop, increment the index variable before backward jump
+ sphead->reset_lex(thd);
+ DBUG_ASSERT(this != thd->lex);
+ if (thd->lex->sp_for_loop_increment(thd, lab->ctx->for_loop()) ||
+ thd->lex->sphead->restore_lex(thd))
+ return true;
+ }
+ return sp_change_context(thd, lab->ctx, false) ||
+ sphead->add_instr_jump(thd, spcont, lab->ip); /* Jump back */
+}
+
+
+bool LEX::sp_continue_statement(THD *thd)
+{
+ sp_label *lab= spcont->find_label_current_loop_start();
+ if (unlikely(!lab))
+ {
+ my_error(ER_SP_LILABEL_MISMATCH, MYF(0), "CONTINUE", "");
+ return true;
+ }
+ DBUG_ASSERT(lab->type == sp_label::ITERATION);
+ return sp_continue_loop(thd, lab);
+}
+
+
+bool LEX::sp_continue_statement(THD *thd, const LEX_CSTRING *label_name)
+{
+ sp_label *lab= spcont->find_label(label_name);
+ if (!lab || lab->type != sp_label::ITERATION)
+ {
+ my_error(ER_SP_LILABEL_MISMATCH, MYF(0), "CONTINUE", label_name->str);
+ return true;
+ }
+ return sp_continue_loop(thd, lab);
+}
+
+
+bool LEX::sp_continue_loop(THD *thd, sp_label *lab, Item *when)
+{
+ DBUG_ASSERT(when);
+ DBUG_ASSERT(sphead == thd->lex->sphead);
+ DBUG_ASSERT(spcont == thd->lex->spcont);
+ sp_instr_jump_if_not *i= new (thd->mem_root)
+ sp_instr_jump_if_not(sphead->instructions(),
+ spcont,
+ when, this);
+ if (unlikely(i == NULL) ||
+ unlikely(sphead->add_instr(i)) ||
+ unlikely(sp_continue_loop(thd, lab)))
+ return true;
+ i->backpatch(sphead->instructions(), spcont);
+ return false;
+}
+
+
+bool sp_expr_lex::sp_continue_when_statement(THD *thd)
+{
+ sp_label *lab= spcont->find_label_current_loop_start();
+ if (unlikely(!lab))
+ {
+ my_error(ER_SP_LILABEL_MISMATCH, MYF(0), "CONTINUE", "");
+ return true;
+ }
+ DBUG_ASSERT(lab->type == sp_label::ITERATION);
+ return sp_continue_loop(thd, lab, get_item());
+}
+
+
+bool sp_expr_lex::sp_continue_when_statement(THD *thd,
+ const LEX_CSTRING *label_name)
+{
+ sp_label *lab= spcont->find_label(label_name);
+ if (!lab || lab->type != sp_label::ITERATION)
+ {
+ my_error(ER_SP_LILABEL_MISMATCH, MYF(0), "CONTINUE", label_name->str);
+ return true;
+ }
+ return sp_continue_loop(thd, lab, get_item());
+}
+
+
+bool LEX::maybe_start_compound_statement(THD *thd)
+{
+ if (!sphead)
+ {
+ if (!make_sp_head(thd, NULL, &sp_handler_procedure, DEFAULT_AGGREGATE))
+ return true;
+ sphead->set_suid(SP_IS_NOT_SUID);
+ sphead->set_body_start(thd, thd->m_parser_state->m_lip.get_cpp_ptr());
+ }
+ return false;
+}
+
+
+bool LEX::sp_push_loop_label(THD *thd, const LEX_CSTRING *label_name)
+{
+ sp_label *lab= spcont->find_label(label_name);
+ if (lab)
+ {
+ my_error(ER_SP_LABEL_REDEFINE, MYF(0), label_name->str);
+ return true;
+ }
+ spcont->push_label(thd, label_name, sphead->instructions(),
+ sp_label::ITERATION);
+ return false;
+}
+
+
+bool LEX::sp_push_loop_empty_label(THD *thd)
+{
+ if (maybe_start_compound_statement(thd))
+ return true;
+ /* Unlabeled controls get an empty label. */
+ spcont->push_label(thd, &empty_clex_str, sphead->instructions(),
+ sp_label::ITERATION);
+ return false;
+}
+
+
+bool LEX::sp_pop_loop_label(THD *thd, const LEX_CSTRING *label_name)
+{
+ sp_label *lab= spcont->pop_label();
+ sphead->backpatch(lab);
+ if (label_name->str &&
+ lex_string_cmp(system_charset_info, label_name,
+ &lab->name) != 0)
+ {
+ my_error(ER_SP_LABEL_MISMATCH, MYF(0), label_name->str);
+ return true;
+ }
+ return false;
+}
+
+
+void LEX::sp_pop_loop_empty_label(THD *thd)
+{
+ sp_label *lab= spcont->pop_label();
+ sphead->backpatch(lab);
+ DBUG_ASSERT(lab->name.length == 0);
+}
+
+
+bool LEX::sp_while_loop_expression(THD *thd, Item *item)
+{
+ sp_instr_jump_if_not *i= new (thd->mem_root)
+ sp_instr_jump_if_not(sphead->instructions(), spcont, item, this);
+ return (unlikely(i == NULL) ||
+ /* Jumping forward */
+ unlikely(sphead->push_backpatch(thd, i, spcont->last_label())) ||
+ unlikely(sphead->new_cont_backpatch(i)) ||
+ unlikely(sphead->add_instr(i)));
+}
+
+
+bool LEX::sp_while_loop_finalize(THD *thd)
+{
+ sp_label *lab= spcont->last_label(); /* Jumping back */
+ sp_instr_jump *i= new (thd->mem_root)
+ sp_instr_jump(sphead->instructions(), spcont, lab->ip);
+ if (unlikely(i == NULL) ||
+ unlikely(sphead->add_instr(i)))
+ return true;
+ sphead->do_cont_backpatch();
+ return false;
+}
+
+
+Item *LEX::create_and_link_Item_trigger_field(THD *thd,
+ const LEX_CSTRING *name,
+ bool new_row)
+{
+ Item_trigger_field *trg_fld;
+
+ if (unlikely(trg_chistics.event == TRG_EVENT_INSERT && !new_row))
+ {
+ my_error(ER_TRG_NO_SUCH_ROW_IN_TRG, MYF(0), "OLD", "on INSERT");
+ return NULL;
+ }
+
+ if (unlikely(trg_chistics.event == TRG_EVENT_DELETE && new_row))
+ {
+ my_error(ER_TRG_NO_SUCH_ROW_IN_TRG, MYF(0), "NEW", "on DELETE");
+ return NULL;
+ }
+
+ DBUG_ASSERT(!new_row ||
+ (trg_chistics.event == TRG_EVENT_INSERT ||
+ trg_chistics.event == TRG_EVENT_UPDATE));
+
+ const bool tmp_read_only=
+ !(new_row && trg_chistics.action_time == TRG_ACTION_BEFORE);
+ trg_fld= new (thd->mem_root)
+ Item_trigger_field(thd, current_context(),
+ new_row ?
+ Item_trigger_field::NEW_ROW:
+ Item_trigger_field::OLD_ROW,
+ *name, SELECT_ACL, tmp_read_only);
+ /*
+ Let us add this item to list of all Item_trigger_field objects
+ in trigger.
+ */
+ if (likely(trg_fld))
+ trg_table_fields.link_in_list(trg_fld, &trg_fld->next_trg_field);
+
+ return trg_fld;
+}
+
+
+Item *LEX::make_item_colon_ident_ident(THD *thd,
+ const Lex_ident_cli_st *ca,
+ const Lex_ident_cli_st *cb)
+{
+ Lex_ident_sys a(thd, ca), b(thd, cb);
+ if (a.is_null() || b.is_null())
+ return NULL; // OEM
+ if (!is_trigger_new_or_old_reference(&a))
+ {
+ thd->parse_error();
+ return NULL;
+ }
+ bool new_row= (a.str[0] == 'N' || a.str[0] == 'n');
+ return create_and_link_Item_trigger_field(thd, &b, new_row);
+}
+
+
+Item *LEX::make_item_plsql_cursor_attr(THD *thd, const LEX_CSTRING *name,
+ plsql_cursor_attr_t attr)
+{
+ uint offset;
+ if (unlikely(!spcont || !spcont->find_cursor(name, &offset, false)))
+ {
+ my_error(ER_SP_CURSOR_MISMATCH, MYF(0), name->str);
+ return NULL;
+ }
+ switch (attr) {
+ case PLSQL_CURSOR_ATTR_ISOPEN:
+ return new (thd->mem_root) Item_func_cursor_isopen(thd, name, offset);
+ case PLSQL_CURSOR_ATTR_FOUND:
+ return new (thd->mem_root) Item_func_cursor_found(thd, name, offset);
+ case PLSQL_CURSOR_ATTR_NOTFOUND:
+ return new (thd->mem_root) Item_func_cursor_notfound(thd, name, offset);
+ case PLSQL_CURSOR_ATTR_ROWCOUNT:
+ return new (thd->mem_root) Item_func_cursor_rowcount(thd, name, offset);
+ }
+ DBUG_ASSERT(0);
+ return NULL;
+}
+
+
+Item *LEX::make_item_sysvar(THD *thd,
+ enum_var_type type,
+ const LEX_CSTRING *name,
+ const LEX_CSTRING *component)
+
+{
+ Item *item;
+ DBUG_ASSERT(name->str);
+ /*
+ "SELECT @@global.global.variable" is not allowed
+ Note, "global" can come through TEXT_STRING_sys.
+ */
+ if (component->str && unlikely(check_reserved_words(name)))
+ {
+ thd->parse_error();
+ return NULL;
+ }
+ if (unlikely(!(item= get_system_var(thd, type, name, component))))
+ return NULL;
+ if (!((Item_func_get_system_var*) item)->is_written_to_binlog())
+ set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_SYSTEM_VARIABLE);
+ return item;
+}
+
+
+static bool param_push_or_clone(THD *thd, LEX *lex, Item_param *item)
+{
+ return !lex->clone_spec_offset ?
+ lex->param_list.push_back(item, thd->mem_root) :
+ item->add_as_clone(thd);
+}
+
+
+Item_param *LEX::add_placeholder(THD *thd, const LEX_CSTRING *name,
+ const char *start, const char *end)
+{
+ if (unlikely(!thd->m_parser_state->m_lip.stmt_prepare_mode))
+ {
+ thd->parse_error(ER_SYNTAX_ERROR, start);
+ return NULL;
+ }
+ if (unlikely(!parsing_options.allows_variable))
+ {
+ my_error(ER_VIEW_SELECT_VARIABLE, MYF(0));
+ return NULL;
+ }
+ Query_fragment pos(thd, sphead, start, end);
+ Item_param *item= new (thd->mem_root) Item_param(thd, name,
+ pos.pos(), pos.length());
+ if (unlikely(!item) || unlikely(param_push_or_clone(thd, this, item)))
+ {
+ my_error(ER_OUT_OF_RESOURCES, MYF(0));
+ return NULL;
+ }
+ return item;
+}
+
+
+bool LEX::add_signal_statement(THD *thd, const sp_condition_value *v)
+{
+ Yacc_state *state= &thd->m_parser_state->m_yacc;
+ sql_command= SQLCOM_SIGNAL;
+ m_sql_cmd= new (thd->mem_root) Sql_cmd_signal(v, state->m_set_signal_info);
+ return m_sql_cmd == NULL;
+}
+
+
+bool LEX::add_resignal_statement(THD *thd, const sp_condition_value *v)
+{
+ Yacc_state *state= &thd->m_parser_state->m_yacc;
+ sql_command= SQLCOM_RESIGNAL;
+ m_sql_cmd= new (thd->mem_root) Sql_cmd_resignal(v, state->m_set_signal_info);
+ return m_sql_cmd == NULL;
+}
+
+
+/*
+ Make an Item when an identifier is found in the FOR loop bounds:
+ FOR rec IN cursor
+ FOR var IN var1 .. xxx
+ FOR var IN row1.field1 .. xxx
+ When we parse the first expression after the "IN" keyword,
+ we don't know yet if it's a cursor name, or a scalar SP variable name,
+ or a field of a ROW SP variable. Here we create Item_field to remember
+ the fully qualified name. Later sp_for_loop_cursor_declarations()
+ detects how to treat this name properly.
+*/
+Item *LEX::create_item_for_loop_bound(THD *thd,
+ const LEX_CSTRING *a,
+ const LEX_CSTRING *b,
+ const LEX_CSTRING *c)
+{
+ /*
+ Pass NULL as the name resolution context.
+ This is OK, fix_fields() won't be called for this Item_field.
+ */
+ return new (thd->mem_root) Item_field(thd, NULL, *a, *b, *c);
+}
+
+
+bool LEX::check_expr_allows_fields_or_error(THD *thd, const char *name) const
+{
+ if (select_stack_top > 0)
+ return false; // OK, fields are allowed
+ my_error(ER_BAD_FIELD_ERROR, MYF(0), name, thd->where);
+ return true; // Error, fields are not allowed
+}
+
+Item *LEX::create_item_ident_nospvar(THD *thd,
+ const Lex_ident_sys_st *a,
+ const Lex_ident_sys_st *b)
+{
+ DBUG_ASSERT(this == thd->lex);
+ /*
+ FIXME This will work ok in simple_ident_nospvar case because
+ we can't meet simple_ident_nospvar in trigger now. But it
+ should be changed in future.
+ */
+ if (is_trigger_new_or_old_reference(a))
+ {
+ bool new_row= (a->str[0]=='N' || a->str[0]=='n');
+
+ return create_and_link_Item_trigger_field(thd, b, new_row);
+ }
+
+ if (unlikely(current_select->no_table_names_allowed))
+ {
+ my_error(ER_TABLENAME_NOT_ALLOWED_HERE, MYF(0), a->str, thd->where);
+ return NULL;
+ }
+
+ if (current_select->parsing_place == FOR_LOOP_BOUND)
+ return create_item_for_loop_bound(thd, &null_clex_str, a, b);
+
+ return create_item_ident_field(thd, Lex_ident_sys(), *a, *b);
+}
+
+
+Item_splocal *LEX::create_item_spvar_row_field(THD *thd,
+ const Sp_rcontext_handler *rh,
+ const Lex_ident_sys *a,
+ const Lex_ident_sys *b,
+ sp_variable *spv,
+ const char *start,
+ const char *end)
+{
+ if (unlikely(!parsing_options.allows_variable))
+ {
+ my_error(ER_VIEW_SELECT_VARIABLE, MYF(0));
+ return NULL;
+ }
+
+ Query_fragment pos(thd, sphead, start, end);
+ Item_splocal *item;
+ if (spv->field_def.is_table_rowtype_ref() ||
+ spv->field_def.is_cursor_rowtype_ref())
+ {
+ if (unlikely(!(item= new (thd->mem_root)
+ Item_splocal_row_field_by_name(thd, rh, a, b, spv->offset,
+ &type_handler_null,
+ pos.pos(), pos.length()))))
+ return NULL;
+ }
+ else
+ {
+ uint row_field_offset;
+ const Spvar_definition *def;
+ if (unlikely(!(def= spv->find_row_field(a, b, &row_field_offset))))
+ return NULL;
+
+ if (unlikely(!(item= new (thd->mem_root)
+ Item_splocal_row_field(thd, rh, a, b,
+ spv->offset, row_field_offset,
+ def->type_handler(),
+ pos.pos(), pos.length()))))
+ return NULL;
+ }
+#ifdef DBUG_ASSERT_EXISTS
+ item->m_sp= sphead;
+#endif
+ safe_to_cache_query=0;
+ return item;
+}
+
+
+my_var *LEX::create_outvar(THD *thd, const LEX_CSTRING *name)
+{
+ const Sp_rcontext_handler *rh;
+ sp_variable *spv;
+ if (likely((spv= find_variable(name, &rh))))
+ return result ? new (thd->mem_root)
+ my_var_sp(rh, name, spv->offset,
+ spv->type_handler(), sphead) :
+ NULL /* EXPLAIN */;
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), name->str);
+ return NULL;
+}
+
+
+my_var *LEX::create_outvar(THD *thd,
+ const LEX_CSTRING *a,
+ const LEX_CSTRING *b)
+{
+ const Sp_rcontext_handler *rh;
+ sp_variable *t;
+ if (unlikely(!(t= find_variable(a, &rh))))
+ {
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), a->str);
+ return NULL;
+ }
+ uint row_field_offset;
+ if (!t->find_row_field(a, b, &row_field_offset))
+ return NULL;
+ return result ?
+ new (thd->mem_root) my_var_sp_row_field(rh, a, b, t->offset,
+ row_field_offset, sphead) :
+ NULL /* EXPLAIN */;
+}
+
+
+Item *LEX::create_item_func_nextval(THD *thd, Table_ident *table_ident)
+{
+ TABLE_LIST *table;
+ if (unlikely(!(table= current_select->add_table_to_list(thd, table_ident, 0,
+ TL_OPTION_SEQUENCE,
+ TL_WRITE_ALLOW_WRITE,
+ MDL_SHARED_WRITE))))
+ return NULL;
+ thd->lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_SYSTEM_FUNCTION);
+ return new (thd->mem_root) Item_func_nextval(thd, table);
+}
+
+
+Item *LEX::create_item_func_lastval(THD *thd, Table_ident *table_ident)
+{
+ TABLE_LIST *table;
+ if (unlikely(!(table= current_select->add_table_to_list(thd, table_ident, 0,
+ TL_OPTION_SEQUENCE,
+ TL_READ,
+ MDL_SHARED_READ))))
+ return NULL;
+ thd->lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_SYSTEM_FUNCTION);
+ return new (thd->mem_root) Item_func_lastval(thd, table);
+}
+
+
+Item *LEX::create_item_func_nextval(THD *thd,
+ const LEX_CSTRING *db,
+ const LEX_CSTRING *name)
+{
+ Table_ident *table_ident;
+ if (unlikely(!(table_ident=
+ new (thd->mem_root) Table_ident(thd, db, name, false))))
+ return NULL;
+ return create_item_func_nextval(thd, table_ident);
+}
+
+
+Item *LEX::create_item_func_lastval(THD *thd,
+ const LEX_CSTRING *db,
+ const LEX_CSTRING *name)
+{
+ Table_ident *table_ident;
+ if (unlikely(!(table_ident=
+ new (thd->mem_root) Table_ident(thd, db, name, false))))
+ return NULL;
+ return create_item_func_lastval(thd, table_ident);
+}
+
+
+Item *LEX::create_item_func_setval(THD *thd, Table_ident *table_ident,
+ longlong nextval, ulonglong round,
+ bool is_used)
+{
+ TABLE_LIST *table;
+ if (unlikely(!(table= current_select->add_table_to_list(thd, table_ident, 0,
+ TL_OPTION_SEQUENCE,
+ TL_WRITE_ALLOW_WRITE,
+ MDL_SHARED_WRITE))))
+ return NULL;
+ return new (thd->mem_root) Item_func_setval(thd, table, nextval, round,
+ is_used);
+}
+
+
+Item *LEX::create_item_ident(THD *thd,
+ const Lex_ident_cli_st *ca,
+ const Lex_ident_cli_st *cb)
+{
+ const char *start= ca->pos();
+ const char *end= cb->end();
+ const Sp_rcontext_handler *rh;
+ sp_variable *spv;
+ DBUG_ASSERT(thd->m_parser_state->m_lip.get_buf() <= start);
+ DBUG_ASSERT(start <= end);
+ DBUG_ASSERT(end <= thd->m_parser_state->m_lip.get_end_of_query());
+ Lex_ident_sys a(thd, ca), b(thd, cb);
+ if (a.is_null() || b.is_null())
+ return NULL; // OEM
+ if ((spv= find_variable(&a, &rh)) &&
+ (spv->field_def.is_row() ||
+ spv->field_def.is_table_rowtype_ref() ||
+ spv->field_def.is_cursor_rowtype_ref()))
+ return create_item_spvar_row_field(thd, rh, &a, &b, spv, start, end);
+
+ if ((thd->variables.sql_mode & MODE_ORACLE) && b.length == 7)
+ {
+ if (!system_charset_info->strnncoll(
+ (const uchar *) b.str, 7,
+ (const uchar *) "NEXTVAL", 7))
+ return create_item_func_nextval(thd, &null_clex_str, &a);
+ else if (!system_charset_info->strnncoll(
+ (const uchar *) b.str, 7,
+ (const uchar *) "CURRVAL", 7))
+ return create_item_func_lastval(thd, &null_clex_str, &a);
+ }
+
+ return create_item_ident_nospvar(thd, &a, &b);
+}
+
+
+Item *LEX::create_item_ident(THD *thd,
+ const Lex_ident_sys_st *a,
+ const Lex_ident_sys_st *b,
+ const Lex_ident_sys_st *c)
+{
+ Lex_ident_sys_st schema= thd->client_capabilities & CLIENT_NO_SCHEMA ?
+ Lex_ident_sys() : *a;
+ if ((thd->variables.sql_mode & MODE_ORACLE) && c->length == 7)
+ {
+ if (!system_charset_info->strnncoll(
+ (const uchar *) c->str, 7,
+ (const uchar *) "NEXTVAL", 7))
+ return create_item_func_nextval(thd, a, b);
+ else if (!system_charset_info->strnncoll(
+ (const uchar *) c->str, 7,
+ (const uchar *) "CURRVAL", 7))
+ return create_item_func_lastval(thd, a, b);
+ }
+
+ if (current_select->no_table_names_allowed)
+ {
+ my_error(ER_TABLENAME_NOT_ALLOWED_HERE, MYF(0), b->str, thd->where);
+ return NULL;
+ }
+
+ if (current_select->parsing_place == FOR_LOOP_BOUND)
+ return create_item_for_loop_bound(thd, &null_clex_str, b, c);
+
+ return create_item_ident_field(thd, schema, *b, *c);
+}
+
+
+Item *LEX::create_item_limit(THD *thd, const Lex_ident_cli_st *ca)
+{
+ DBUG_ASSERT(thd->m_parser_state->m_lip.get_buf() <= ca->pos());
+ DBUG_ASSERT(ca->pos() <= ca->end());
+ DBUG_ASSERT(ca->end() <= thd->m_parser_state->m_lip.get_end_of_query());
+
+ const Sp_rcontext_handler *rh;
+ sp_variable *spv;
+ Lex_ident_sys sa(thd, ca);
+ if (sa.is_null())
+ return NULL; // EOM
+ if (!(spv= find_variable(&sa, &rh)))
+ {
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), sa.str);
+ return NULL;
+ }
+
+ Query_fragment pos(thd, sphead, ca->pos(), ca->end());
+ Item_splocal *item;
+ if (unlikely(!(item= new (thd->mem_root)
+ Item_splocal(thd, rh, &sa,
+ spv->offset, spv->type_handler(),
+ clone_spec_offset ? 0 : pos.pos(),
+ clone_spec_offset ? 0 : pos.length()))))
+ return NULL;
+#ifdef DBUG_ASSERT_EXISTS
+ item->m_sp= sphead;
+#endif
+ safe_to_cache_query= 0;
+
+ if (!item->is_valid_limit_clause_variable_with_error())
+ return NULL;
+
+ item->limit_clause_param= true;
+ return item;
+}
+
+
+Item *LEX::create_item_limit(THD *thd,
+ const Lex_ident_cli_st *ca,
+ const Lex_ident_cli_st *cb)
+{
+ DBUG_ASSERT(thd->m_parser_state->m_lip.get_buf() <= ca->pos());
+ DBUG_ASSERT(ca->pos() <= cb->end());
+ DBUG_ASSERT(cb->end() <= thd->m_parser_state->m_lip.get_end_of_query());
+
+ const Sp_rcontext_handler *rh;
+ sp_variable *spv;
+ Lex_ident_sys sa(thd, ca), sb(thd, cb);
+ if (unlikely(sa.is_null() || sb.is_null()))
+ return NULL; // EOM
+ if (!(spv= find_variable(&sa, &rh)))
+ {
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), sa.str);
+ return NULL;
+ }
+ // Qualified %TYPE variables are not possible
+ DBUG_ASSERT(!spv->field_def.column_type_ref());
+ Item_splocal *item;
+ if (unlikely(!(item= create_item_spvar_row_field(thd, rh, &sa, &sb, spv,
+ ca->pos(), cb->end()))))
+ return NULL;
+ if (!item->is_valid_limit_clause_variable_with_error())
+ return NULL;
+ item->limit_clause_param= true;
+ return item;
+}
+
+
+bool LEX::set_user_variable(THD *thd, const LEX_CSTRING *name, Item *val)
+{
+ Item_func_set_user_var *item;
+ set_var_user *var;
+ if (unlikely(!(item= new (thd->mem_root) Item_func_set_user_var(thd, name,
+ val))) ||
+ unlikely(!(var= new (thd->mem_root) set_var_user(item))))
+ return true;
+ if (unlikely(var_list.push_back(var, thd->mem_root)))
+ return true;
+ return false;
+}
+
+
+Item *LEX::create_item_ident_field(THD *thd,
+ const Lex_ident_sys_st &db,
+ const Lex_ident_sys_st &table,
+ const Lex_ident_sys_st &name)
+{
+ if (check_expr_allows_fields_or_error(thd, name.str))
+ return NULL;
+
+ if (current_select->parsing_place != IN_HAVING ||
+ current_select->get_in_sum_expr() > 0)
+ return new (thd->mem_root) Item_field(thd, current_context(),
+ db, table, name);
+
+ return new (thd->mem_root) Item_ref(thd, current_context(),
+ db, table, name);
+}
+
+
+Item *LEX::create_item_ident_sp(THD *thd, Lex_ident_sys_st *name,
+ const char *start,
+ const char *end)
+{
+ DBUG_ASSERT(thd->m_parser_state->m_lip.get_buf() <= start);
+ DBUG_ASSERT(start <= end);
+ DBUG_ASSERT(end <= thd->m_parser_state->m_lip.get_end_of_query());
+
+ const Sp_rcontext_handler *rh;
+ sp_variable *spv;
+ uint unused_off;
+ DBUG_ASSERT(spcont);
+ DBUG_ASSERT(sphead);
+ if ((spv= find_variable(name, &rh)))
+ {
+ /* We're compiling a stored procedure and found a variable */
+ if (!parsing_options.allows_variable)
+ {
+ my_error(ER_VIEW_SELECT_VARIABLE, MYF(0));
+ return NULL;
+ }
+
+ Query_fragment pos(thd, sphead, start, end);
+ uint f_pos= clone_spec_offset ? 0 : pos.pos();
+ uint f_length= clone_spec_offset ? 0 : pos.length();
+ Item_splocal *splocal= spv->field_def.is_column_type_ref() ?
+ new (thd->mem_root) Item_splocal_with_delayed_data_type(thd, rh, name,
+ spv->offset,
+ f_pos, f_length) :
+ new (thd->mem_root) Item_splocal(thd, rh, name,
+ spv->offset, spv->type_handler(),
+ f_pos, f_length);
+ if (unlikely(splocal == NULL))
+ return NULL;
+#ifdef DBUG_ASSERT_EXISTS
+ splocal->m_sp= sphead;
+#endif
+ safe_to_cache_query= 0;
+ return splocal;
+ }
+
+ if (thd->variables.sql_mode & MODE_ORACLE)
+ {
+ if (lex_string_eq(name, STRING_WITH_LEN("SQLCODE")))
+ return new (thd->mem_root) Item_func_sqlcode(thd);
+ if (lex_string_eq(name, STRING_WITH_LEN("SQLERRM")))
+ return new (thd->mem_root) Item_func_sqlerrm(thd);
+ }
+
+ if (fields_are_impossible() &&
+ (current_select->parsing_place != FOR_LOOP_BOUND ||
+ spcont->find_cursor(name, &unused_off, false) == NULL))
+ {
+ // we are out of SELECT or FOR so it is syntax error
+ my_error(ER_SP_UNDECLARED_VAR, MYF(0), name->str);
+ return NULL;
+ }
+
+ if (current_select->parsing_place == FOR_LOOP_BOUND)
+ return create_item_for_loop_bound(thd, &null_clex_str, &null_clex_str,
+ name);
+
+ return create_item_ident_nosp(thd, name);
+}
+
+
+
+bool LEX::set_variable(const Lex_ident_sys_st *name, Item *item)
+{
+ sp_pcontext *ctx;
+ const Sp_rcontext_handler *rh;
+ sp_variable *spv= find_variable(name, &ctx, &rh);
+ return spv ? sphead->set_local_variable(thd, ctx, rh, spv, item, this, true) :
+ set_system_variable(option_type, name, item);
+}
+
+
+/**
+ Generate instructions for:
+ SET x.y= expr;
+*/
+bool LEX::set_variable(const Lex_ident_sys_st *name1,
+ const Lex_ident_sys_st *name2,
+ Item *item)
+{
+ const Sp_rcontext_handler *rh;
+ sp_pcontext *ctx;
+ sp_variable *spv;
+ if (spcont && (spv= find_variable(name1, &ctx, &rh)))
+ {
+ if (spv->field_def.is_table_rowtype_ref() ||
+ spv->field_def.is_cursor_rowtype_ref())
+ return sphead->set_local_variable_row_field_by_name(thd, ctx,
+ rh,
+ spv, name2,
+ item, this);
+ // A field of a ROW variable
+ uint row_field_offset;
+ return !spv->find_row_field(name1, name2, &row_field_offset) ||
+ sphead->set_local_variable_row_field(thd, ctx, rh,
+ spv, row_field_offset,
+ item, this);
+ }
+
+ if (is_trigger_new_or_old_reference(name1))
+ return set_trigger_field(name1, name2, item);
+
+ return set_system_variable(thd, option_type, name1, name2, item);
+}
+
+
+bool LEX::set_default_system_variable(enum_var_type var_type,
+ const Lex_ident_sys_st *name,
+ Item *val)
+{
+ static Lex_ident_sys default_base_name= {STRING_WITH_LEN("default")};
+ sys_var *var= find_sys_var(thd, name->str, name->length);
+ if (!var)
+ return true;
+ if (unlikely(!var->is_struct()))
+ {
+ my_error(ER_VARIABLE_IS_NOT_STRUCT, MYF(0), name->str);
+ return true;
+ }
+ return set_system_variable(var_type, var, &default_base_name, val);
+}
+
+
+bool LEX::set_system_variable(enum_var_type var_type,
+ const Lex_ident_sys_st *name,
+ Item *val)
+{
+ sys_var *var= find_sys_var(thd, name->str, name->length);
+ DBUG_ASSERT(thd->is_error() || var != NULL);
+ static Lex_ident_sys null_str;
+ return likely(var) ? set_system_variable(var_type, var, &null_str, val) : true;
+}
+
+
+bool LEX::set_system_variable(THD *thd, enum_var_type var_type,
+ const Lex_ident_sys_st *name1,
+ const Lex_ident_sys_st *name2,
+ Item *val)
+{
+ sys_var *tmp;
+ if (unlikely(check_reserved_words(name1)) ||
+ unlikely(!(tmp= find_sys_var(thd, name2->str, name2->length, true))))
+ {
+ my_error(ER_UNKNOWN_STRUCTURED_VARIABLE, MYF(0),
+ (int) name1->length, name1->str);
+ return true;
+ }
+ if (unlikely(!tmp->is_struct()))
+ {
+ my_error(ER_VARIABLE_IS_NOT_STRUCT, MYF(0), name2->str);
+ return true;
+ }
+ return set_system_variable(var_type, tmp, name1, val);
+}
+
+
+bool LEX::set_trigger_field(const LEX_CSTRING *name1, const LEX_CSTRING *name2,
+ Item *val)
+{
+ DBUG_ASSERT(is_trigger_new_or_old_reference(name1));
+ if (unlikely(name1->str[0]=='O' || name1->str[0]=='o'))
+ {
+ my_error(ER_TRG_CANT_CHANGE_ROW, MYF(0), "OLD", "");
+ return true;
+ }
+ if (unlikely(trg_chistics.event == TRG_EVENT_DELETE))
+ {
+ my_error(ER_TRG_NO_SUCH_ROW_IN_TRG, MYF(0), "NEW", "on DELETE");
+ return true;
+ }
+ if (unlikely(trg_chistics.action_time == TRG_ACTION_AFTER))
+ {
+ my_error(ER_TRG_CANT_CHANGE_ROW, MYF(0), "NEW", "after ");
+ return true;
+ }
+ return set_trigger_new_row(name2, val);
+}
+
+
+#ifdef MYSQL_SERVER
+uint binlog_unsafe_map[256];
+
+#define UNSAFE(a, b, c) \
+ { \
+ DBUG_PRINT("unsafe_mixed_statement", ("SETTING BASE VALUES: %s, %s, %02X", \
+ LEX::stmt_accessed_table_string(a), \
+ LEX::stmt_accessed_table_string(b), \
+ c)); \
+ unsafe_mixed_statement(a, b, c); \
+ }
+
+/*
+ Sets the combination given by "a" and "b" and automatically combinations
+ given by other types of access, i.e. 2^(8 - 2), as unsafe.
+
+ It may happen a colision when automatically defining a combination as unsafe.
+ For that reason, a combination has its unsafe condition redefined only when
+ the new_condition is greater then the old. For instance,
+
+ . (BINLOG_DIRECT_ON & TRX_CACHE_NOT_EMPTY) is never overwritten by
+ . (BINLOG_DIRECT_ON | BINLOG_DIRECT_OFF).
+*/
+void unsafe_mixed_statement(LEX::enum_stmt_accessed_table a,
+ LEX::enum_stmt_accessed_table b, uint condition)
+{
+ int type= 0;
+ int index= (1U << a) | (1U << b);
+
+
+ for (type= 0; type < 256; type++)
+ {
+ if ((type & index) == index)
+ {
+ binlog_unsafe_map[type] |= condition;
+ }
+ }
+}
+/*
+ The BINLOG_* AND TRX_CACHE_* values can be combined by using '&' or '|',
+ which means that both conditions need to be satisfied or any of them is
+ enough. For example,
+
+ . BINLOG_DIRECT_ON & TRX_CACHE_NOT_EMPTY means that the statment is
+ unsafe when the option is on and trx-cache is not empty;
+
+ . BINLOG_DIRECT_ON | BINLOG_DIRECT_OFF means the statement is unsafe
+ in all cases.
+
+ . TRX_CACHE_EMPTY | TRX_CACHE_NOT_EMPTY means the statement is unsafe
+ in all cases. Similar as above.
+*/
+void binlog_unsafe_map_init()
+{
+ memset((void*) binlog_unsafe_map, 0, sizeof(uint) * 256);
+
+ /*
+ Classify a statement as unsafe when there is a mixed statement and an
+ on-going transaction at any point of the execution if:
+
+ 1. The mixed statement is about to update a transactional table and
+ a non-transactional table.
+
+ 2. The mixed statement is about to update a transactional table and
+ read from a non-transactional table.
+
+ 3. The mixed statement is about to update a non-transactional table
+ and temporary transactional table.
+
+ 4. The mixed statement is about to update a temporary transactional
+ table and read from a non-transactional table.
+
+ 5. The mixed statement is about to update a transactional table and
+ a temporary non-transactional table.
+
+ 6. The mixed statement is about to update a transactional table and
+ read from a temporary non-transactional table.
+
+ 7. The mixed statement is about to update a temporary transactional
+ table and temporary non-transactional table.
+
+ 8. The mixed statement is about to update a temporary transactional
+ table and read from a temporary non-transactional table.
+
+ After updating a transactional table if:
+
+ 9. The mixed statement is about to update a non-transactional table
+ and read from a transactional table.
+
+ 10. The mixed statement is about to update a non-transactional table
+ and read from a temporary transactional table.
+
+ 11. The mixed statement is about to update a temporary non-transactional
+ table and read from a transactional table.
+
+ 12. The mixed statement is about to update a temporary non-transactional
+ table and read from a temporary transactional table.
+
+ 13. The mixed statement is about to update a temporary non-transactional
+ table and read from a non-transactional table.
+
+ The reason for this is that locks acquired may not protected a concurrent
+ transaction of interfering in the current execution and by consequence in
+ the result.
+ */
+ /* Case 1. */
+ UNSAFE(LEX::STMT_WRITES_TRANS_TABLE, LEX::STMT_WRITES_NON_TRANS_TABLE,
+ BINLOG_DIRECT_ON | BINLOG_DIRECT_OFF);
+ /* Case 2. */
+ UNSAFE(LEX::STMT_WRITES_TRANS_TABLE, LEX::STMT_READS_NON_TRANS_TABLE,
+ BINLOG_DIRECT_ON | BINLOG_DIRECT_OFF);
+ /* Case 3. */
+ UNSAFE(LEX::STMT_WRITES_NON_TRANS_TABLE, LEX::STMT_WRITES_TEMP_TRANS_TABLE,
+ BINLOG_DIRECT_ON | BINLOG_DIRECT_OFF);
+ /* Case 4. */
+ UNSAFE(LEX::STMT_WRITES_TEMP_TRANS_TABLE, LEX::STMT_READS_NON_TRANS_TABLE,
+ BINLOG_DIRECT_ON | BINLOG_DIRECT_OFF);
+ /* Case 5. */
+ UNSAFE(LEX::STMT_WRITES_TRANS_TABLE, LEX::STMT_WRITES_TEMP_NON_TRANS_TABLE,
+ BINLOG_DIRECT_ON);
+ /* Case 6. */
+ UNSAFE(LEX::STMT_WRITES_TRANS_TABLE, LEX::STMT_READS_TEMP_NON_TRANS_TABLE,
+ BINLOG_DIRECT_ON);
+ /* Case 7. */
+ UNSAFE(LEX::STMT_WRITES_TEMP_TRANS_TABLE, LEX::STMT_WRITES_TEMP_NON_TRANS_TABLE,
+ BINLOG_DIRECT_ON);
+ /* Case 8. */
+ UNSAFE(LEX::STMT_WRITES_TEMP_TRANS_TABLE, LEX::STMT_READS_TEMP_NON_TRANS_TABLE,
+ BINLOG_DIRECT_ON);
+ /* Case 9. */
+ UNSAFE(LEX::STMT_WRITES_NON_TRANS_TABLE, LEX::STMT_READS_TRANS_TABLE,
+ (BINLOG_DIRECT_ON | BINLOG_DIRECT_OFF) & TRX_CACHE_NOT_EMPTY);
+ /* Case 10 */
+ UNSAFE(LEX::STMT_WRITES_NON_TRANS_TABLE, LEX::STMT_READS_TEMP_TRANS_TABLE,
+ (BINLOG_DIRECT_ON | BINLOG_DIRECT_OFF) & TRX_CACHE_NOT_EMPTY);
+ /* Case 11. */
+ UNSAFE(LEX::STMT_WRITES_TEMP_NON_TRANS_TABLE, LEX::STMT_READS_TRANS_TABLE,
+ BINLOG_DIRECT_ON & TRX_CACHE_NOT_EMPTY);
+ /* Case 12. */
+ UNSAFE(LEX::STMT_WRITES_TEMP_NON_TRANS_TABLE, LEX::STMT_READS_TEMP_TRANS_TABLE,
+ BINLOG_DIRECT_ON & TRX_CACHE_NOT_EMPTY);
+ /* Case 13. */
+ UNSAFE(LEX::STMT_WRITES_TEMP_NON_TRANS_TABLE, LEX::STMT_READS_NON_TRANS_TABLE,
+ BINLOG_DIRECT_OFF & TRX_CACHE_NOT_EMPTY);
+}
+#endif
+
+
+/**
+ @brief
+ Collect fiels that are used in the GROUP BY of this st_select_lex
+
+ @param thd The thread handle
+
+ @details
+ This method looks through the fields that are used in the GROUP BY of this
+ st_select_lex and saves info on these fields.
+*/
+
+void st_select_lex::collect_grouping_fields_for_derived(THD *thd,
+ ORDER *grouping_list)
+{
+ grouping_tmp_fields.empty();
+ List_iterator<Item> li(join->fields_list);
+ Item *item= li++;
+ for (uint i= 0; i < master_unit()->derived->table->s->fields;
+ i++, (item=li++))
+ {
+ for (ORDER *ord= grouping_list; ord; ord= ord->next)
+ {
+ if ((*ord->item)->eq((Item*)item, 0))
+ {
+ Field_pair *grouping_tmp_field=
+ new Field_pair(master_unit()->derived->table->field[i], item);
+ grouping_tmp_fields.push_back(grouping_tmp_field);
+ }
+ }
+ }
+}
+
+
+/**
+ Collect fields that are used in the GROUP BY of this SELECT
+*/
+
+bool st_select_lex::collect_grouping_fields(THD *thd)
+{
+ grouping_tmp_fields.empty();
+
+ for (ORDER *ord= group_list.first; ord; ord= ord->next)
+ {
+ Item *item= *ord->item;
+ if (item->type() != Item::FIELD_ITEM &&
+ !(item->type() == Item::REF_ITEM &&
+ item->real_type() == Item::FIELD_ITEM &&
+ ((((Item_ref *) item)->ref_type() == Item_ref::VIEW_REF) ||
+ (((Item_ref *) item)->ref_type() == Item_ref::REF))))
+ continue;
+
+ Field_pair *grouping_tmp_field=
+ new Field_pair(((Item_field *)item->real_item())->field, item);
+ if (grouping_tmp_fields.push_back(grouping_tmp_field, thd->mem_root))
+ return false;
+ }
+ if (grouping_tmp_fields.elements)
+ return false;
+ return true;
+}
+
+
+/**
+ @brief
+ For a condition check possibility of exraction a formula over grouping fields
+
+ @param thd The thread handle
+ @param cond The condition whose subformulas are to be analyzed
+ @param checker The checker callback function to be applied to the nodes
+ of the tree of the object
+
+ @details
+ This method traverses the AND-OR condition cond and for each subformula of
+ the condition it checks whether it can be usable for the extraction of a
+ condition over the grouping fields of this select. The method uses
+ the call-back parameter checker to check whether a primary formula
+ depends only on grouping fields.
+ The subformulas that are not usable are marked with the flag NO_EXTRACTION_FL.
+ The subformulas that can be entierly extracted are marked with the flag
+ FULL_EXTRACTION_FL.
+ @note
+ This method is called before any call of extract_cond_for_grouping_fields.
+ The flag NO_EXTRACTION_FL set in a subformula allows to avoid building clone
+ for the subformula when extracting the pushable condition.
+ The flag FULL_EXTRACTION_FL allows to delete later all top level conjuncts
+ from cond.
+*/
+
+void
+st_select_lex::check_cond_extraction_for_grouping_fields(THD *thd, Item *cond)
+{
+ if (cond->get_extraction_flag() == NO_EXTRACTION_FL)
+ return;
+ cond->clear_extraction_flag();
+ if (cond->type() == Item::COND_ITEM)
+ {
+ Item_cond_and *and_cond=
+ (((Item_cond*) cond)->functype() == Item_func::COND_AND_FUNC) ?
+ ((Item_cond_and*) cond) : 0;
+
+ List<Item> *arg_list= ((Item_cond*) cond)->argument_list();
+ List_iterator<Item> li(*arg_list);
+ uint count= 0; // to count items not containing NO_EXTRACTION_FL
+ uint count_full= 0; // to count items with FULL_EXTRACTION_FL
+ Item *item;
+ while ((item=li++))
+ {
+ check_cond_extraction_for_grouping_fields(thd, item);
+ if (item->get_extraction_flag() != NO_EXTRACTION_FL)
+ {
+ count++;
+ if (item->get_extraction_flag() == FULL_EXTRACTION_FL)
+ count_full++;
+ }
+ else if (!and_cond)
+ break;
+ }
+ if ((and_cond && count == 0) || item)
+ cond->set_extraction_flag(NO_EXTRACTION_FL);
+ if (count_full == arg_list->elements)
+ {
+ cond->set_extraction_flag(FULL_EXTRACTION_FL);
+ }
+ if (cond->get_extraction_flag() != 0)
+ {
+ li.rewind();
+ while ((item=li++))
+ item->clear_extraction_flag();
+ }
+ }
+ else
+ {
+ int fl= cond->excl_dep_on_grouping_fields(this) && !cond->is_expensive() ?
+ FULL_EXTRACTION_FL : NO_EXTRACTION_FL;
+ cond->set_extraction_flag(fl);
+ }
+}
+
+
+/**
+ @brief
+ Build condition extractable from the given one depended on grouping fields
+
+ @param thd The thread handle
+ @param cond The condition from which the condition depended
+ on grouping fields is to be extracted
+ @param no_top_clones If it's true then no clones for the top fully
+ extractable conjuncts are built
+
+ @details
+ For the given condition cond this method finds out what condition depended
+ only on the grouping fields can be extracted from cond. If such condition C
+ exists the method builds the item for it.
+ This method uses the flags NO_EXTRACTION_FL and FULL_EXTRACTION_FL set by the
+ preliminary call of st_select_lex::check_cond_extraction_for_grouping_fields
+ to figure out whether a subformula depends only on these fields or not.
+ @note
+ The built condition C is always implied by the condition cond
+ (cond => C). The method tries to build the least restictive such
+ condition (i.e. for any other condition C' such that cond => C'
+ we have C => C').
+ @note
+ The build item is not ready for usage: substitution for the field items
+ has to be done and it has to be re-fixed.
+
+ @retval
+ the built condition depended only on grouping fields if such a condition exists
+ NULL if there is no such a condition
+*/
+
+Item *st_select_lex::build_cond_for_grouping_fields(THD *thd, Item *cond,
+ bool no_top_clones)
+{
+ if (cond->get_extraction_flag() == FULL_EXTRACTION_FL)
+ {
+ if (no_top_clones)
+ return cond;
+ cond->clear_extraction_flag();
+ return cond->build_clone(thd);
+ }
+ if (cond->type() == Item::COND_ITEM)
+ {
+ bool cond_and= false;
+ Item_cond *new_cond;
+ if (((Item_cond*) cond)->functype() == Item_func::COND_AND_FUNC)
+ {
+ cond_and= true;
+ new_cond= new (thd->mem_root) Item_cond_and(thd);
+ }
+ else
+ new_cond= new (thd->mem_root) Item_cond_or(thd);
+ if (unlikely(!new_cond))
+ return 0;
+ List_iterator<Item> li(*((Item_cond*) cond)->argument_list());
+ Item *item;
+ while ((item=li++))
+ {
+ if (item->get_extraction_flag() == NO_EXTRACTION_FL)
+ {
+ DBUG_ASSERT(cond_and);
+ item->clear_extraction_flag();
+ continue;
+ }
+ Item *fix= build_cond_for_grouping_fields(thd, item,
+ no_top_clones & cond_and);
+ if (unlikely(!fix))
+ {
+ if (cond_and)
+ continue;
+ break;
+ }
+ new_cond->argument_list()->push_back(fix, thd->mem_root);
+ }
+
+ if (!cond_and && item)
+ {
+ while((item= li++))
+ item->clear_extraction_flag();
+ return 0;
+ }
+ switch (new_cond->argument_list()->elements)
+ {
+ case 0:
+ return 0;
+ case 1:
+ return new_cond->argument_list()->head();
+ default:
+ return new_cond;
+ }
+ }
+ return 0;
+}
+
+
+bool st_select_lex::set_nest_level(int new_nest_level)
+{
+ DBUG_ENTER("st_select_lex::set_nest_level");
+ DBUG_PRINT("enter", ("select #%d %p nest level: %d",
+ select_number, this, new_nest_level));
+ if (new_nest_level > (int) MAX_SELECT_NESTING)
+ {
+ my_error(ER_TOO_HIGH_LEVEL_OF_NESTING_FOR_SELECT, MYF(0));
+ DBUG_RETURN(TRUE);
+ }
+ nest_level= new_nest_level;
+ new_nest_level++;
+ for (SELECT_LEX_UNIT *u= first_inner_unit(); u; u= u->next_unit())
+ {
+ if (u->set_nest_level(new_nest_level))
+ DBUG_RETURN(TRUE);
+ }
+ DBUG_RETURN(FALSE);
+}
+
+bool st_select_lex_unit::set_nest_level(int new_nest_level)
+{
+ DBUG_ENTER("st_select_lex_unit::set_nest_level");
+ for(SELECT_LEX *sl= first_select(); sl; sl= sl->next_select())
+ {
+ if (sl->set_nest_level(new_nest_level))
+ DBUG_RETURN(TRUE);
+ }
+ if (fake_select_lex &&
+ fake_select_lex->set_nest_level(new_nest_level))
+ DBUG_RETURN(TRUE);
+ DBUG_RETURN(FALSE);
+}
+
+
+bool st_select_lex::check_parameters(SELECT_LEX *main_select)
+{
+ DBUG_ENTER("st_select_lex::check_parameters");
+ DBUG_PRINT("enter", ("select #%d %p nest level: %d",
+ select_number, this, nest_level));
+
+
+ if ((options & OPTION_PROCEDURE_CLAUSE) &&
+ (!parent_lex->selects_allow_procedure ||
+ next_select() != NULL ||
+ this != master_unit()->first_select() ||
+ nest_level != 0))
+ {
+ my_error(ER_CANT_USE_OPTION_HERE, MYF(0), "PROCEDURE");
+ DBUG_RETURN(TRUE);
+ }
+
+ if ((options & SELECT_HIGH_PRIORITY) && this != main_select)
+ {
+ my_error(ER_CANT_USE_OPTION_HERE, MYF(0), "HIGH_PRIORITY");
+ DBUG_RETURN(TRUE);
+ }
+ if ((options & OPTION_BUFFER_RESULT) && this != main_select)
+ {
+ my_error(ER_CANT_USE_OPTION_HERE, MYF(0), "SQL_BUFFER_RESULT");
+ DBUG_RETURN(TRUE);
+ }
+ if ((options & OPTION_FOUND_ROWS) && this != main_select)
+ {
+ my_error(ER_CANT_USE_OPTION_HERE, MYF(0), "SQL_CALC_FOUND_ROWS");
+ DBUG_RETURN(TRUE);
+ }
+ if (options & OPTION_NO_QUERY_CACHE)
+ {
+ /*
+ Allow this flag only on the first top-level SELECT statement, if
+ SQL_CACHE wasn't specified.
+ */
+ if (this != main_select)
+ {
+ my_error(ER_CANT_USE_OPTION_HERE, MYF(0), "SQL_NO_CACHE");
+ DBUG_RETURN(TRUE);
+ }
+ if (parent_lex->sql_cache == LEX::SQL_CACHE)
+ {
+ my_error(ER_WRONG_USAGE, MYF(0), "SQL_CACHE", "SQL_NO_CACHE");
+ DBUG_RETURN(TRUE);
+ }
+ parent_lex->safe_to_cache_query=0;
+ parent_lex->sql_cache= LEX::SQL_NO_CACHE;
+ }
+ if (options & OPTION_TO_QUERY_CACHE)
+ {
+ /*
+ Allow this flag only on the first top-level SELECT statement, if
+ SQL_NO_CACHE wasn't specified.
+ */
+ if (this != main_select)
+ {
+ my_error(ER_CANT_USE_OPTION_HERE, MYF(0), "SQL_CACHE");
+ DBUG_RETURN(TRUE);
+ }
+ if (parent_lex->sql_cache == LEX::SQL_NO_CACHE)
+ {
+ my_error(ER_WRONG_USAGE, MYF(0), "SQL_NO_CACHE", "SQL_CACHE");
+ DBUG_RETURN(TRUE);
+ }
+ parent_lex->safe_to_cache_query=1;
+ parent_lex->sql_cache= LEX::SQL_CACHE;
+ }
+
+ for (SELECT_LEX_UNIT *u= first_inner_unit(); u; u= u->next_unit())
+ {
+ if (u->check_parameters(main_select))
+ DBUG_RETURN(TRUE);
+ }
+ DBUG_RETURN(FALSE);
+}
+
+
+bool st_select_lex_unit::check_parameters(SELECT_LEX *main_select)
+{
+ for(SELECT_LEX *sl= first_select(); sl; sl= sl->next_select())
+ {
+ if (sl->check_parameters(main_select))
+ return TRUE;
+ }
+ return fake_select_lex && fake_select_lex->check_parameters(main_select);
+}
+
+
+bool LEX::check_main_unit_semantics()
+{
+ if (unit.set_nest_level(0) ||
+ unit.check_parameters(first_select_lex()))
+ return TRUE;
+ if (check_cte_dependencies_and_resolve_references())
+ return TRUE;
+ return FALSE;
+}
+
+int set_statement_var_if_exists(THD *thd, const char *var_name,
+ size_t var_name_length, ulonglong value)
+{
+ sys_var *sysvar;
+ if (unlikely(thd->lex->sql_command == SQLCOM_CREATE_VIEW))
+ {
+ my_error(ER_VIEW_SELECT_CLAUSE, MYF(0), "[NO]WAIT");
+ return 1;
+ }
+ if (unlikely(thd->lex->sphead))
+ {
+ my_error(ER_SP_BADSTATEMENT, MYF(0), "[NO]WAIT");
+ return 1;
+ }
+ if ((sysvar= find_sys_var(thd, var_name, var_name_length, true)))
+ {
+ Item *item= new (thd->mem_root) Item_uint(thd, value);
+ set_var *var= new (thd->mem_root) set_var(thd, OPT_SESSION, sysvar,
+ &null_clex_str, item);
+
+ if (unlikely(!item) || unlikely(!var) ||
+ unlikely(thd->lex->stmt_var_list.push_back(var, thd->mem_root)))
+ {
+ my_error(ER_OUT_OF_RESOURCES, MYF(0));
+ return 1;
+ }
+ }
+ return 0;
+}
+
+
+bool LEX::sp_add_cfetch(THD *thd, const LEX_CSTRING *name)
+{
+ uint offset;
+ sp_instr_cfetch *i;
+
+ if (!spcont->find_cursor(name, &offset, false))
+ {
+ my_error(ER_SP_CURSOR_MISMATCH, MYF(0), name->str);
+ return true;
+ }
+ i= new (thd->mem_root)
+ sp_instr_cfetch(sphead->instructions(), spcont, offset,
+ !(thd->variables.sql_mode & MODE_ORACLE));
+ if (unlikely(i == NULL) || unlikely(sphead->add_instr(i)))
+ return true;
+ return false;
+}
+
+
+bool LEX::sp_add_agg_cfetch()
+{
+ sphead->m_flags|= sp_head::HAS_AGGREGATE_INSTR;
+ sp_instr_agg_cfetch *i=
+ new (thd->mem_root) sp_instr_agg_cfetch(sphead->instructions(), spcont);
+ return i == NULL || sphead->add_instr(i);
+}
+
+
+bool LEX::create_or_alter_view_finalize(THD *thd, Table_ident *table_ident)
+{
+ sql_command= SQLCOM_CREATE_VIEW;
+ /* first table in list is target VIEW name */
+ if (!first_select_lex()->add_table_to_list(thd, table_ident, NULL,
+ TL_OPTION_UPDATING,
+ TL_IGNORE,
+ MDL_EXCLUSIVE))
+ return true;
+ query_tables->open_strategy= TABLE_LIST::OPEN_STUB;
+ return false;
+}
+
+
+bool LEX::add_alter_view(THD *thd, uint16 algorithm,
+ enum_view_suid suid,
+ Table_ident *table_ident)
+{
+ if (unlikely(sphead))
+ {
+ my_error(ER_SP_BADSTATEMENT, MYF(0), "ALTER VIEW");
+ return true;
+ }
+ if (unlikely(!(create_view= new (thd->mem_root)
+ Create_view_info(VIEW_ALTER, algorithm, suid))))
+ return true;
+ return create_or_alter_view_finalize(thd, table_ident);
+}
+
+
+bool LEX::add_create_view(THD *thd, DDL_options_st ddl,
+ uint16 algorithm, enum_view_suid suid,
+ Table_ident *table_ident)
+{
+ if (unlikely(set_create_options_with_check(ddl)))
+ return true;
+ if (unlikely(!(create_view= new (thd->mem_root)
+ Create_view_info(ddl.or_replace() ?
+ VIEW_CREATE_OR_REPLACE :
+ VIEW_CREATE_NEW,
+ algorithm, suid))))
+ return true;
+ return create_or_alter_view_finalize(thd, table_ident);
+}
+
+
+bool LEX::call_statement_start(THD *thd, sp_name *name)
+{
+ Database_qualified_name pkgname(&null_clex_str, &null_clex_str);
+ const Sp_handler *sph= &sp_handler_procedure;
+ sql_command= SQLCOM_CALL;
+ value_list.empty();
+ if (unlikely(sph->sp_resolve_package_routine(thd, thd->lex->sphead,
+ name, &sph, &pkgname)))
+ return true;
+ if (unlikely(!(m_sql_cmd= new (thd->mem_root) Sql_cmd_call(name, sph))))
+ return true;
+ sph->add_used_routine(this, thd, name);
+ if (pkgname.m_name.length)
+ sp_handler_package_body.add_used_routine(this, thd, &pkgname);
+ return false;
+}
+
+
+bool LEX::call_statement_start(THD *thd, const Lex_ident_sys_st *name)
+{
+ sp_name *spname= make_sp_name(thd, name);
+ return unlikely(!spname) || call_statement_start(thd, spname);
+}
+
+
+bool LEX::call_statement_start(THD *thd, const Lex_ident_sys_st *name1,
+ const Lex_ident_sys_st *name2)
+{
+ sp_name *spname= make_sp_name(thd, name1, name2);
+ return unlikely(!spname) || call_statement_start(thd, spname);
+}
+
+
+sp_package *LEX::get_sp_package() const
+{
+ return sphead ? sphead->get_package() : NULL;
+}
+
+
+sp_package *LEX::create_package_start(THD *thd,
+ enum_sql_command command,
+ const Sp_handler *sph,
+ const sp_name *name_arg,
+ DDL_options_st options)
+{
+ sp_package *pkg;
+
+ if (unlikely(sphead))
+ {
+ my_error(ER_SP_NO_RECURSIVE_CREATE, MYF(0), sph->type_str());
+ return NULL;
+ }
+ if (unlikely(set_command_with_check(command, options)))
+ return NULL;
+ if (sph->type() == SP_TYPE_PACKAGE_BODY)
+ {
+ /*
+ If we start parsing a "CREATE PACKAGE BODY", we need to load
+ the corresponding "CREATE PACKAGE", for the following reasons:
+ 1. "CREATE PACKAGE BODY" is allowed only if "CREATE PACKAGE"
+ was done earlier for the same package name.
+ So if "CREATE PACKAGE" does not exist, we throw an error here.
+ 2. When parsing "CREATE PACKAGE BODY", we need to know all package
+ public and private routine names, to translate procedure and
+ function calls correctly.
+ For example, this statement inside a package routine:
+ CALL p;
+ can be translated to:
+ CALL db.pkg.p; -- p is a known (public or private) package routine
+ CALL db.p; -- p is not a known package routine
+ */
+ sp_head *spec;
+ int ret= sp_handler_package_spec.
+ sp_cache_routine_reentrant(thd, name_arg, &spec);
+ if (unlikely(!spec))
+ {
+ if (!ret)
+ my_error(ER_SP_DOES_NOT_EXIST, MYF(0),
+ "PACKAGE", ErrConvDQName(name_arg).ptr());
+ return 0;
+ }
+ }
+ if (unlikely(!(pkg= sp_package::create(this, name_arg, sph))))
+ return NULL;
+ pkg->reset_thd_mem_root(thd);
+ pkg->init(this);
+ pkg->make_qname(pkg->get_main_mem_root(), &pkg->m_qname);
+ sphead= pkg;
+ return pkg;
+}
+
+
+bool LEX::create_package_finalize(THD *thd,
+ const sp_name *name,
+ const sp_name *name2,
+ const char *body_start,
+ const char *body_end)
+{
+ if (name2 &&
+ (name2->m_explicit_name != name->m_explicit_name ||
+ strcmp(name2->m_db.str, name->m_db.str) ||
+ !Sp_handler::eq_routine_name(name2->m_name, name->m_name)))
+ {
+ bool exp= name2->m_explicit_name || name->m_explicit_name;
+ my_error(ER_END_IDENTIFIER_DOES_NOT_MATCH, MYF(0),
+ exp ? ErrConvDQName(name2).ptr() : name2->m_name.str,
+ exp ? ErrConvDQName(name).ptr() : name->m_name.str);
+ return true;
+ }
+ // TODO: reuse code in LEX::create_package_finalize and sp_head::set_stmt_end
+ sphead->m_body.length= body_end - body_start;
+ if (unlikely(!(sphead->m_body.str= thd->strmake(body_start,
+ sphead->m_body.length))))
+ return true;
+
+ size_t not_used;
+ Lex_input_stream *lip= & thd->m_parser_state->m_lip;
+ sphead->m_defstr.length= lip->get_cpp_ptr() - lip->get_cpp_buf();
+ sphead->m_defstr.str= thd->strmake(lip->get_cpp_buf(), sphead->m_defstr.length);
+ trim_whitespace(thd->charset(), &sphead->m_defstr, &not_used);
+
+ sphead->restore_thd_mem_root(thd);
+ sp_package *pkg= sphead->get_package();
+ DBUG_ASSERT(pkg);
+ return sphead->check_group_aggregate_instructions_forbid() ||
+ pkg->validate_after_parser(thd);
+}
+
+
+bool LEX::add_grant_command(THD *thd, const List<LEX_COLUMN> &columns)
+{
+ if (columns.elements)
+ {
+ thd->parse_error();
+ return true;
+ }
+ return false;
+}
+
+
+Item *LEX::make_item_func_substr(THD *thd, Item *a, Item *b, Item *c)
+{
+ return (thd->variables.sql_mode & MODE_ORACLE) ?
+ new (thd->mem_root) Item_func_substr_oracle(thd, a, b, c) :
+ new (thd->mem_root) Item_func_substr(thd, a, b, c);
+}
+
+
+Item *LEX::make_item_func_substr(THD *thd, Item *a, Item *b)
+{
+ return (thd->variables.sql_mode & MODE_ORACLE) ?
+ new (thd->mem_root) Item_func_substr_oracle(thd, a, b) :
+ new (thd->mem_root) Item_func_substr(thd, a, b);
+}
+
+
+Item *LEX::make_item_func_replace(THD *thd,
+ Item *org,
+ Item *find,
+ Item *replace)
+{
+ return (thd->variables.sql_mode & MODE_ORACLE) ?
+ new (thd->mem_root) Item_func_replace_oracle(thd, org, find, replace) :
+ new (thd->mem_root) Item_func_replace(thd, org, find, replace);
+}
+
+
+bool SELECT_LEX::vers_push_field(THD *thd, TABLE_LIST *table,
+ const LEX_CSTRING field_name)
+{
+ DBUG_ASSERT(field_name.str);
+ Item_field *fld= new (thd->mem_root) Item_field(thd, &context,
+ table->db,
+ table->alias,
+ field_name);
+ if (unlikely(!fld) || unlikely(item_list.push_back(fld)))
+ return true;
+
+ if (thd->lex->view_list.elements)
+ {
+ LEX_CSTRING *l;
+ if (unlikely(!(l= thd->make_clex_string(field_name.str,
+ field_name.length))) ||
+ unlikely(thd->lex->view_list.push_back(l)))
+ return true;
+ }
+
+ return false;
+}
+
+
+Item *Lex_trim_st::make_item_func_trim_std(THD *thd) const
+{
+ if (m_remove)
+ {
+ switch (m_spec) {
+ case TRIM_BOTH:
+ return new (thd->mem_root) Item_func_trim(thd, m_source, m_remove);
+ case TRIM_LEADING:
+ return new (thd->mem_root) Item_func_ltrim(thd, m_source, m_remove);
+ case TRIM_TRAILING:
+ return new (thd->mem_root) Item_func_rtrim(thd, m_source, m_remove);
+ }
+ }
+
+ switch (m_spec) {
+ case TRIM_BOTH:
+ return new (thd->mem_root) Item_func_trim(thd, m_source);
+ case TRIM_LEADING:
+ return new (thd->mem_root) Item_func_ltrim(thd, m_source);
+ case TRIM_TRAILING:
+ return new (thd->mem_root) Item_func_rtrim(thd, m_source);
+ }
+ DBUG_ASSERT(0);
+ return NULL;
+}
+
+
+Item *Lex_trim_st::make_item_func_trim_oracle(THD *thd) const
+{
+ if (m_remove)
+ {
+ switch (m_spec) {
+ case TRIM_BOTH:
+ return new (thd->mem_root) Item_func_trim_oracle(thd, m_source, m_remove);
+ case TRIM_LEADING:
+ return new (thd->mem_root) Item_func_ltrim_oracle(thd, m_source, m_remove);
+ case TRIM_TRAILING:
+ return new (thd->mem_root) Item_func_rtrim_oracle(thd, m_source, m_remove);
+ }
+ }
+
+ switch (m_spec) {
+ case TRIM_BOTH:
+ return new (thd->mem_root) Item_func_trim_oracle(thd, m_source);
+ case TRIM_LEADING:
+ return new (thd->mem_root) Item_func_ltrim_oracle(thd, m_source);
+ case TRIM_TRAILING:
+ return new (thd->mem_root) Item_func_rtrim_oracle(thd, m_source);
+ }
+ DBUG_ASSERT(0);
+ return NULL;
+}
+
+
+Item *Lex_trim_st::make_item_func_trim(THD *thd) const
+{
+ return (thd->variables.sql_mode & MODE_ORACLE) ?
+ make_item_func_trim_oracle(thd) :
+ make_item_func_trim_std(thd);
+}
+
+
+Item *LEX::make_item_func_call_generic(THD *thd, Lex_ident_cli_st *cdb,
+ Lex_ident_cli_st *cname, List<Item> *args)
+{
+ Lex_ident_sys db(thd, cdb), name(thd, cname);
+ if (db.is_null() || name.is_null())
+ return NULL; // EOM
+ /*
+ The following in practice calls:
+ <code>Create_sp_func::create()</code>
+ and builds a stored function.
+
+ However, it's important to maintain the interface between the
+ parser and the implementation in item_create.cc clean,
+ since this will change with WL#2128 (SQL PATH):
+ - INFORMATION_SCHEMA.version() is the SQL 99 syntax for the native
+ function version(),
+ - MySQL.version() is the SQL 2003 syntax for the native function
+ version() (a vendor can specify any schema).
+ */
+
+ if (!name.str || check_db_name((LEX_STRING*) static_cast<LEX_CSTRING*>(&db)))
+ {
+ my_error(ER_WRONG_DB_NAME, MYF(0), db.str);
+ return NULL;
+ }
+ if (check_routine_name(&name))
+ return NULL;
+
+ Create_qfunc *builder= find_qualified_function_builder(thd);
+ DBUG_ASSERT(builder);
+ return builder->create_with_db(thd, &db, &name, true, args);
+}
+
+
+Item *LEX::make_item_func_call_native_or_parse_error(THD *thd,
+ Lex_ident_cli_st &name,
+ List<Item> *args)
+{
+ Create_func *builder= find_native_function_builder(thd, &name);
+ DBUG_EXECUTE_IF("make_item_func_call_native_simulate_not_found",
+ builder= NULL;);
+ if (builder)
+ return builder->create_func(thd, &name, args);
+ thd->parse_error(ER_SYNTAX_ERROR, name.end());
+ return NULL;
+}
+
+
+Item *LEX::create_item_qualified_asterisk(THD *thd,
+ const Lex_ident_sys_st *name)
+{
+ Item *item;
+ if (!(item= new (thd->mem_root) Item_field(thd, current_context(),
+ null_clex_str, *name,
+ star_clex_str)))
+ return NULL;
+ current_select->with_wild++;
+ return item;
+}
+
+
+Item *LEX::create_item_qualified_asterisk(THD *thd,
+ const Lex_ident_sys_st *a,
+ const Lex_ident_sys_st *b)
+{
+ Item *item;
+ Lex_ident_sys_st schema= thd->client_capabilities & CLIENT_NO_SCHEMA ?
+ Lex_ident_sys() : *a;
+ if (!(item= new (thd->mem_root) Item_field(thd, current_context(),
+ schema, *b, star_clex_str)))
+ return NULL;
+ current_select->with_wild++;
+ return item;
+}
+
+
+bool Lex_ident_sys_st::copy_ident_cli(THD *thd, const Lex_ident_cli_st *str)
+{
+ return thd->to_ident_sys_alloc(this, str);
+}
+
+bool Lex_ident_sys_st::copy_keyword(THD *thd, const Lex_ident_cli_st *str)
+{
+ return thd->make_lex_string(static_cast<LEX_CSTRING*>(this),
+ str->str, str->length) == NULL;
+}
+
+bool Lex_ident_sys_st::copy_or_convert(THD *thd,
+ const Lex_ident_cli_st *src,
+ CHARSET_INFO *cs)
+{
+ if (!src->is_8bit())
+ return copy_keyword(thd, src); // 7bit string makes a wellformed identifier
+ return convert(thd, src, cs);
+}
+
+
+bool Lex_ident_sys_st::copy_sys(THD *thd, const LEX_CSTRING *src)
+{
+ if (thd->check_string_for_wellformedness(src->str, src->length,
+ system_charset_info))
+ return true;
+ return thd->make_lex_string(this, src->str, src->length) == NULL;
+}
+
+
+bool Lex_ident_sys_st::convert(THD *thd,
+ const LEX_CSTRING *src, CHARSET_INFO *cs)
+{
+ LEX_STRING tmp;
+ if (thd->convert_with_error(system_charset_info, &tmp, cs,
+ src->str, src->length))
+ return true;
+ str= tmp.str;
+ length= tmp.length;
+ return false;
+}
+
+
+bool Lex_ident_sys_st::to_size_number(ulonglong *to) const
+{
+ ulonglong number;
+ uint text_shift_number= 0;
+ longlong prefix_number;
+ const char *start_ptr= str;
+ size_t str_len= length;
+ const char *end_ptr= start_ptr + str_len;
+ int error;
+ prefix_number= my_strtoll10(start_ptr, (char**) &end_ptr, &error);
+ if (likely((start_ptr + str_len - 1) == end_ptr))
+ {
+ switch (end_ptr[0])
+ {
+ case 'g':
+ case 'G': text_shift_number+=30; break;
+ case 'm':
+ case 'M': text_shift_number+=20; break;
+ case 'k':
+ case 'K': text_shift_number+=10; break;
+ default:
+ my_error(ER_WRONG_SIZE_NUMBER, MYF(0));
+ return true;
+ }
+ if (unlikely(prefix_number >> 31))
+ {
+ my_error(ER_SIZE_OVERFLOW_ERROR, MYF(0));
+ return true;
+ }
+ number= prefix_number << text_shift_number;
+ }
+ else
+ {
+ my_error(ER_WRONG_SIZE_NUMBER, MYF(0));
+ return true;
+ }
+ *to= number;
+ return false;
+}
+
+
+bool LEX::part_values_current(THD *thd)
+{
+ partition_element *elem= part_info->curr_part_elem;
+ if (!is_partition_management())
+ {
+ if (unlikely(part_info->part_type != VERSIONING_PARTITION))
+ {
+ my_error(ER_PARTITION_WRONG_TYPE, MYF(0), "SYSTEM_TIME");
+ return true;
+ }
+ }
+ else
+ {
+ DBUG_ASSERT(create_last_non_select_table);
+ DBUG_ASSERT(create_last_non_select_table->table_name.str);
+ // FIXME: other ALTER commands?
+ my_error(ER_VERS_WRONG_PARTS, MYF(0),
+ create_last_non_select_table->table_name.str);
+ return true;
+ }
+ elem->type= partition_element::CURRENT;
+ DBUG_ASSERT(part_info->vers_info);
+ part_info->vers_info->now_part= elem;
+ return false;
+}
+
+
+bool LEX::part_values_history(THD *thd)
+{
+ partition_element *elem= part_info->curr_part_elem;
+ if (!is_partition_management())
+ {
+ if (unlikely(part_info->part_type != VERSIONING_PARTITION))
+ {
+ my_error(ER_PARTITION_WRONG_TYPE, MYF(0), "SYSTEM_TIME");
+ return true;
+ }
+ }
+ else
+ {
+ part_info->vers_init_info(thd);
+ elem->id= UINT_MAX32;
+ }
+ DBUG_ASSERT(part_info->vers_info);
+ if (unlikely(part_info->vers_info->now_part))
+ {
+ DBUG_ASSERT(create_last_non_select_table);
+ DBUG_ASSERT(create_last_non_select_table->table_name.str);
+ my_error(ER_VERS_WRONG_PARTS, MYF(0),
+ create_last_non_select_table->table_name.str);
+ return true;
+ }
+ elem->type= partition_element::HISTORY;
+ return false;
+}
+
+
+bool LEX::last_field_generated_always_as_row_start_or_end(Lex_ident *p,
+ const char *type,
+ uint flag)
+{
+ if (unlikely(p->str))
+ {
+ my_error(ER_VERS_DUPLICATE_ROW_START_END, MYF(0), type,
+ last_field->field_name.str);
+ return true;
+ }
+ last_field->flags|= (flag | NOT_NULL_FLAG);
+ DBUG_ASSERT(p);
+ *p= last_field->field_name;
+ return false;
+}
+
+
+
+bool LEX::last_field_generated_always_as_row_start()
+{
+ Vers_parse_info &info= vers_get_info();
+ Lex_ident *p= &info.as_row.start;
+ return last_field_generated_always_as_row_start_or_end(p, "START",
+ VERS_SYS_START_FLAG);
+}
+
+
+bool LEX::last_field_generated_always_as_row_end()
+{
+ Vers_parse_info &info= vers_get_info();
+ Lex_ident *p= &info.as_row.end;
+ return last_field_generated_always_as_row_start_or_end(p, "END",
+ VERS_SYS_END_FLAG);
+}
+
+void st_select_lex_unit::reset_distinct()
+{
+ union_distinct= NULL;
+ for(SELECT_LEX *sl= first_select()->next_select();
+ sl;
+ sl= sl->next_select())
+ {
+ if (sl->distinct)
+ {
+ union_distinct= sl;
+ }
+ }
+}
+
+
+void LEX::save_values_list_state()
+{
+ current_select->save_many_values= many_values;
+ current_select->save_insert_list= insert_list;
+}
+
+
+void LEX::restore_values_list_state()
+{
+ many_values= current_select->save_many_values;
+ insert_list= current_select->save_insert_list;
+}
+
+
+void st_select_lex_unit::fix_distinct()
+{
+ if (union_distinct && this != union_distinct->master_unit())
+ reset_distinct();
+}
+
+
+void st_select_lex_unit::register_select_chain(SELECT_LEX *first_sel)
+{
+ DBUG_ASSERT(first_sel != 0);
+ slave= first_sel;
+ first_sel->prev= &slave;
+ for(SELECT_LEX *sel=first_sel; sel; sel= sel->next_select())
+ {
+ sel->master= (st_select_lex_node *)this;
+ uncacheable|= sel->uncacheable;
+ }
+}
+
+
+void st_select_lex::register_unit(SELECT_LEX_UNIT *unit,
+ Name_resolution_context *outer_context)
+{
+ if ((unit->next= slave))
+ slave->prev= &unit->next;
+ unit->prev= &slave;
+ slave= unit;
+ unit->master= this;
+ uncacheable|= unit->uncacheable;
+
+ for(SELECT_LEX *sel= unit->first_select();sel; sel= sel->next_select())
+ {
+ sel->context.outer_context= outer_context;
+ }
+}
+
+
+void st_select_lex::add_statistics(SELECT_LEX_UNIT *unit)
+{
+ for (;
+ unit;
+ unit= unit->next_unit())
+ for(SELECT_LEX *child= unit->first_select();
+ child;
+ child= child->next_select())
+ {
+ /*
+ A subselect can add fields to an outer select.
+ Reserve space for them.
+ */
+ select_n_where_fields+= child->select_n_where_fields;
+ /*
+ Aggregate functions in having clause may add fields
+ to an outer select. Count them also.
+ */
+ select_n_having_items+= child->select_n_having_items;
+ }
+}
+
+
+bool LEX::main_select_push(bool service)
+{
+ DBUG_ENTER("LEX::main_select_push");
+ DBUG_PRINT("info", ("service: %u", service));
+ current_select_number= ++thd->lex->stmt_lex->current_select_number;
+ builtin_select.select_number= current_select_number;
+ builtin_select.is_service_select= service;
+ if (push_select(&builtin_select))
+ DBUG_RETURN(TRUE);
+ DBUG_RETURN(FALSE);
+}
+
+void Lex_select_lock::set_to(SELECT_LEX *sel)
+{
+ if (defined_lock)
+ {
+ if (sel->master_unit() &&
+ sel == sel->master_unit()->fake_select_lex)
+ sel->master_unit()->set_lock_to_the_last_select(*this);
+ else
+ {
+ sel->parent_lex->safe_to_cache_query= 0;
+ if (update_lock)
+ {
+ sel->lock_type= TL_WRITE;
+ sel->set_lock_for_tables(TL_WRITE, false);
+ }
+ else
+ {
+ sel->lock_type= TL_READ_WITH_SHARED_LOCKS;
+ sel->set_lock_for_tables(TL_READ_WITH_SHARED_LOCKS, false);
+ }
+ }
+ }
+}
+
+bool Lex_order_limit_lock::set_to(SELECT_LEX *sel)
+{
+ /*TODO: lock */
+ //if (lock.defined_lock && sel == sel->master_unit()->fake_select_lex)
+ // return TRUE;
+ if (lock.defined_timeout)
+ {
+ THD *thd= sel->parent_lex->thd;
+ if (set_statement_var_if_exists(thd,
+ C_STRING_WITH_LEN("lock_wait_timeout"),
+ lock.timeout) ||
+ set_statement_var_if_exists(thd,
+ C_STRING_WITH_LEN("innodb_lock_wait_timeout"),
+ lock.timeout))
+ return TRUE;
+ }
+ lock.set_to(sel);
+ sel->explicit_limit= limit.explicit_limit;
+ sel->select_limit= limit.select_limit;
+ sel->offset_limit= limit.offset_limit;
+ if (order_list)
+ {
+ if (sel->get_linkage() != GLOBAL_OPTIONS_TYPE &&
+ sel->olap != UNSPECIFIED_OLAP_TYPE &&
+ (sel->get_linkage() != UNION_TYPE || sel->braces))
+ {
+ my_error(ER_WRONG_USAGE, MYF(0),
+ "CUBE/ROLLUP", "ORDER BY");
+ return TRUE;
+ }
+ sel->order_list= *(order_list);
+ }
+ sel->is_set_query_expr_tail= true;
+ return FALSE;
+}
+
+
+static void change_item_list_context(List<Item> *list,
+ Name_resolution_context *context)
+{
+ List_iterator_fast<Item> it (*list);
+ Item *item;
+ while((item= it++))
+ {
+ item->walk(&Item::change_context_processor, FALSE, (void *)context);
+ }
+}
+
+
+bool LEX::insert_select_hack(SELECT_LEX *sel)
+{
+ DBUG_ENTER("LEX::insert_select_hack");
+
+ DBUG_ASSERT(first_select_lex() == &builtin_select);
+ DBUG_ASSERT(sel != NULL);
+
+ DBUG_ASSERT(builtin_select.first_inner_unit() == NULL);
+
+ if (builtin_select.link_prev)
+ {
+ if ((*builtin_select.link_prev= builtin_select.link_next))
+ ((st_select_lex *)builtin_select.link_next)->link_prev=
+ builtin_select.link_prev;
+ builtin_select.link_prev= NULL; // indicator of removal
+ }
+
+ if (set_main_unit(sel->master_unit()))
+ return true;
+
+ DBUG_ASSERT(builtin_select.table_list.elements == 1);
+ TABLE_LIST *insert_table= builtin_select.table_list.first;
+
+ if (!(insert_table->next_local= sel->table_list.first))
+ {
+ sel->table_list.next= &insert_table->next_local;
+ }
+ sel->table_list.first= insert_table;
+ sel->table_list.elements++;
+ insert_table->select_lex= sel;
+
+ sel->context.first_name_resolution_table= insert_table;
+ builtin_select.context= sel->context;
+ change_item_list_context(&field_list, &sel->context);
+
+ if (sel->tvc && !sel->next_select() &&
+ (sql_command == SQLCOM_INSERT_SELECT ||
+ sql_command == SQLCOM_REPLACE_SELECT))
+ {
+ DBUG_PRINT("info", ("'Usual' INSERT detected"));
+ many_values= sel->tvc->lists_of_values;
+ sel->options= sel->tvc->select_options;
+ sel->tvc= NULL;
+ if (sql_command == SQLCOM_INSERT_SELECT)
+ sql_command= SQLCOM_INSERT;
+ else
+ sql_command= SQLCOM_REPLACE;
+ }
+
+
+ for (SELECT_LEX *sel= all_selects_list;
+ sel;
+ sel= sel->next_select_in_list())
+ {
+ if (sel->select_number != 1)
+ sel->select_number--;
+ };
+
+ DBUG_RETURN(FALSE);
+}
+
+
+/**
+ Create an Item_singlerow_subselect for a query expression.
+*/
+
+Item *LEX::create_item_query_expression(THD *thd,
+ st_select_lex_unit *unit)
+{
+ if (clause_that_disallows_subselect)
+ {
+ my_error(ER_SUBQUERIES_NOT_SUPPORTED, MYF(0),
+ clause_that_disallows_subselect);
+ return NULL;
+ }
+
+ // Add the subtree of subquery to the current SELECT_LEX
+ SELECT_LEX *curr_sel= select_stack_head();
+ DBUG_ASSERT(current_select == curr_sel ||
+ (curr_sel == NULL && current_select == &builtin_select));
+ if (!curr_sel)
+ {
+ curr_sel= &builtin_select;
+ curr_sel->register_unit(unit, &curr_sel->context);
+ curr_sel->add_statistics(unit);
+ }
+
+ return new (thd->mem_root)
+ Item_singlerow_subselect(thd, unit->first_select());
+}
+
+
+SELECT_LEX_UNIT *LEX::parsed_select_expr_start(SELECT_LEX *s1, SELECT_LEX *s2,
+ enum sub_select_type unit_type,
+ bool distinct)
+{
+ SELECT_LEX_UNIT *res;
+ SELECT_LEX *sel1;
+ SELECT_LEX *sel2;
+ if (!s1->next_select())
+ sel1= s1;
+ else
+ {
+ sel1= wrap_unit_into_derived(s1->master_unit());
+ if (!sel1)
+ return NULL;
+ }
+ if (!s2->next_select())
+ sel2= s2;
+ else
+ {
+ sel2= wrap_unit_into_derived(s2->master_unit());
+ if (!sel2)
+ return NULL;
+ }
+ sel1->link_neighbour(sel2);
+ sel2->set_linkage_and_distinct(unit_type, distinct);
+ sel2->first_nested= sel1->first_nested= sel1;
+ res= create_unit(sel1);
+ if (res == NULL)
+ return NULL;
+ res->pre_last_parse= sel1;
+ push_select(res->fake_select_lex);
+ return res;
+}
+
+
+SELECT_LEX_UNIT *LEX::parsed_select_expr_cont(SELECT_LEX_UNIT *unit,
+ SELECT_LEX *s2,
+ enum sub_select_type unit_type,
+ bool distinct, bool oracle)
+{
+ DBUG_ASSERT(!s2->next_select());
+ SELECT_LEX *sel1= s2;
+ SELECT_LEX *last= unit->pre_last_parse->next_select();
+
+ int cmp= oracle? 0 : cmp_unit_op(unit_type, last->get_linkage());
+ if (cmp == 0)
+ {
+ sel1->first_nested= last->first_nested;
+ }
+ else if (cmp > 0)
+ {
+ last->first_nested= unit->pre_last_parse;
+ sel1->first_nested= last;
+ }
+ else /* cmp < 0 */
+ {
+ SELECT_LEX *first_in_nest= last->first_nested;
+ if (first_in_nest->first_nested != first_in_nest)
+ {
+ /* There is a priority jump starting from first_in_nest */
+ if ((last= create_priority_nest(first_in_nest)) == NULL)
+ return NULL;
+ unit->fix_distinct();
+ }
+ sel1->first_nested= last->first_nested;
+ }
+ last->link_neighbour(sel1);
+ sel1->set_master_unit(unit);
+ sel1->set_linkage_and_distinct(unit_type, distinct);
+ unit->pre_last_parse= last;
+ return unit;
+}
+
+
+/**
+ Add primary expression as the next term in a given query expression body
+ pruducing a new query expression body
+*/
+
+SELECT_LEX_UNIT *
+LEX::add_primary_to_query_expression_body(SELECT_LEX_UNIT *unit,
+ SELECT_LEX *sel,
+ enum sub_select_type unit_type,
+ bool distinct,
+ bool oracle)
+{
+ SELECT_LEX *sel2= sel;
+ if (sel->master_unit() && sel->master_unit()->first_select()->next_select())
+ {
+ sel2= wrap_unit_into_derived(sel->master_unit());
+ if (!sel2)
+ return NULL;
+ }
+ SELECT_LEX *sel1= unit->first_select();
+ if (!sel1->next_select())
+ unit= parsed_select_expr_start(sel1, sel2, unit_type, distinct);
+ else
+ unit= parsed_select_expr_cont(unit, sel2, unit_type, distinct, oracle);
+ return unit;
+}
+
+
+SELECT_LEX_UNIT *
+LEX::add_primary_to_query_expression_body(SELECT_LEX_UNIT *unit,
+ SELECT_LEX *sel,
+ enum sub_select_type unit_type,
+ bool distinct)
+{
+ return
+ add_primary_to_query_expression_body(unit, sel, unit_type, distinct,
+ thd->variables.sql_mode & MODE_ORACLE);
+}
+
+/**
+ Add query primary to a parenthesized query primary
+ pruducing a new query expression body
+*/
+
+SELECT_LEX_UNIT *
+LEX::add_primary_to_query_expression_body_ext_parens(
+ SELECT_LEX_UNIT *unit,
+ SELECT_LEX *sel,
+ enum sub_select_type unit_type,
+ bool distinct)
+{
+ SELECT_LEX *sel1= unit->first_select();
+ if (unit->first_select()->next_select())
+ {
+ sel1= wrap_unit_into_derived(unit);
+ if (!sel1)
+ return NULL;
+ if (!create_unit(sel1))
+ return NULL;
+ }
+ SELECT_LEX *sel2= sel;
+ if (sel->master_unit() && sel->master_unit()->first_select()->next_select())
+ {
+ sel2= wrap_unit_into_derived(sel->master_unit());
+ if (!sel2)
+ return NULL;
+ }
+ unit= parsed_select_expr_start(sel1, sel2, unit_type, distinct);
+ return unit;
+}
+
+
+/**
+ Process multi-operand query expression body
+*/
+
+bool LEX::parsed_multi_operand_query_expression_body(SELECT_LEX_UNIT *unit)
+{
+ SELECT_LEX *first_in_nest=
+ unit->pre_last_parse->next_select()->first_nested;
+ if (first_in_nest->first_nested != first_in_nest)
+ {
+ /* There is a priority jump starting from first_in_nest */
+ if (create_priority_nest(first_in_nest) == NULL)
+ return true;
+ unit->fix_distinct();
+ }
+ return false;
+}
+
+
+/**
+ Add non-empty tail to a query expression body
+*/
+
+SELECT_LEX_UNIT *LEX::add_tail_to_query_expression_body(SELECT_LEX_UNIT *unit,
+ Lex_order_limit_lock *l)
+{
+ DBUG_ASSERT(l != NULL);
+ pop_select();
+ SELECT_LEX *sel= unit->first_select()->next_select() ? unit->fake_select_lex :
+ unit->first_select();
+ l->set_to(sel);
+ return unit;
+}
+
+
+/**
+ Add non-empty tail to a parenthesized query primary
+*/
+
+SELECT_LEX_UNIT *
+LEX::add_tail_to_query_expression_body_ext_parens(SELECT_LEX_UNIT *unit,
+ Lex_order_limit_lock *l)
+{
+ SELECT_LEX *sel= unit->first_select()->next_select() ? unit->fake_select_lex :
+ unit->first_select();
+
+ DBUG_ASSERT(l != NULL);
+
+ pop_select();
+ if (sel->is_set_query_expr_tail)
+ {
+ if (!l->order_list && !sel->explicit_limit)
+ l->order_list= &sel->order_list;
+ else
+ {
+ if (!unit)
+ return NULL;
+ sel= wrap_unit_into_derived(unit);
+ if (!sel)
+ return NULL;
+ if (!create_unit(sel))
+ return NULL;
+ }
+ }
+ l->set_to(sel);
+ return sel->master_unit();
+}
+
+
+/**
+ Process subselect parsing
+*/
+
+SELECT_LEX *LEX::parsed_subselect(SELECT_LEX_UNIT *unit)
+{
+ if (clause_that_disallows_subselect)
+ {
+ my_error(ER_SUBQUERIES_NOT_SUPPORTED, MYF(0),
+ clause_that_disallows_subselect);
+ return NULL;
+ }
+
+ // Add the subtree of subquery to the current SELECT_LEX
+ SELECT_LEX *curr_sel= select_stack_head();
+ DBUG_ASSERT(current_select == curr_sel ||
+ (curr_sel == NULL && current_select == &builtin_select));
+ if (curr_sel)
+ {
+ curr_sel->register_unit(unit, context_stack.head());
+ curr_sel->add_statistics(unit);
+ }
+
+ return unit->first_select();
+}
+
+
+/**
+ Process INSERT-like select
+*/
+
+bool LEX::parsed_insert_select(SELECT_LEX *first_select)
+{
+ if (sql_command == SQLCOM_INSERT ||
+ sql_command == SQLCOM_REPLACE)
+ {
+ if (sql_command == SQLCOM_INSERT)
+ sql_command= SQLCOM_INSERT_SELECT;
+ else
+ sql_command= SQLCOM_REPLACE_SELECT;
+ }
+ insert_select_hack(first_select);
+ if (check_main_unit_semantics())
+ return true;
+
+ // fix "main" select
+ SELECT_LEX *blt __attribute__((unused))= pop_select();
+ DBUG_ASSERT(blt == &builtin_select);
+ push_select(first_select);
+ return false;
+}
+
+
+bool LEX::parsed_TVC_start()
+{
+ SELECT_LEX *sel;
+ save_values_list_state();
+ many_values.empty();
+ insert_list= 0;
+ if (!(sel= alloc_select(TRUE)) ||
+ push_select(sel))
+ return true;
+ sel->init_select();
+ sel->braces= FALSE; // just initialisation
+ return false;
+}
+
+
+SELECT_LEX *LEX::parsed_TVC_end()
+{
+ SELECT_LEX *res= pop_select(); // above TVC select
+ if (!(res->tvc=
+ new (thd->mem_root) table_value_constr(many_values,
+ res,
+ res->options)))
+ return NULL;
+ restore_values_list_state();
+ return res;
+}
+
+
+
+TABLE_LIST *LEX::parsed_derived_table(SELECT_LEX_UNIT *unit,
+ int for_system_time,
+ LEX_CSTRING *alias)
+{
+ TABLE_LIST *res;
+ derived_tables|= DERIVED_SUBQUERY;
+ unit->first_select()->set_linkage(DERIVED_TABLE_TYPE);
+
+ // Add the subtree of subquery to the current SELECT_LEX
+ SELECT_LEX *curr_sel= select_stack_head();
+ DBUG_ASSERT(current_select == curr_sel ||
+ (curr_sel == NULL && current_select == &builtin_select));
+
+ Table_ident *ti= new (thd->mem_root) Table_ident(unit);
+ if (ti == NULL)
+ return NULL;
+ if (!(res= curr_sel->add_table_to_list(thd, ti, alias, 0,
+ TL_READ, MDL_SHARED_READ)))
+ return NULL;
+ if (for_system_time)
+ {
+ res->vers_conditions= vers_conditions;
+ }
+ return res;
+}
+
+bool LEX::parsed_create_view(SELECT_LEX_UNIT *unit, int check)
+{
+ SQL_I_List<TABLE_LIST> *save= &first_select_lex()->table_list;
+ if (set_main_unit(unit))
+ return true;
+ if (check_main_unit_semantics())
+ return true;
+ first_select_lex()->table_list.push_front(save);
+ current_select= first_select_lex();
+ size_t len= thd->m_parser_state->m_lip.get_cpp_ptr() -
+ create_view->select.str;
+ void *create_view_select= thd->memdup(create_view->select.str, len);
+ create_view->select.length= len;
+ create_view->select.str= (char *) create_view_select;
+ size_t not_used;
+ trim_whitespace(thd->charset(),
+ &create_view->select, &not_used);
+ create_view->check= check;
+ parsing_options.allows_variable= TRUE;
+ return false;
+}
+
+bool LEX::select_finalize(st_select_lex_unit *expr)
+{
+ sql_command= SQLCOM_SELECT;
+ selects_allow_into= TRUE;
+ selects_allow_procedure= TRUE;
+ if (set_main_unit(expr))
+ return true;
+ return check_main_unit_semantics();
+}
+
+
+bool LEX::select_finalize(st_select_lex_unit *expr, Lex_select_lock l)
+{
+ return expr->set_lock_to_the_last_select(l) ||
+ select_finalize(expr);
+}
+
+
+/*
+ "IN" and "EXISTS" subselect can appear in two statement types:
+
+ 1. Statements that can have table columns, such as SELECT, DELETE, UPDATE
+ 2. Statements that cannot have table columns, e.g:
+ RETURN ((1) IN (SELECT * FROM t1))
+ IF ((1) IN (SELECT * FROM t1))
+
+ Statements of the first type call master_select_push() in the beginning.
+ In such case everything is properly linked.
+
+ Statements of the second type do not call mastr_select_push().
+ Here we catch the second case and relink thd->lex->builtin_select and
+ select_lex to properly point to each other.
+
+ QQ: Shouldn't subselects of other type also call relink_hack()?
+ QQ: Can we do it at constructor time instead?
+*/
+
+void LEX::relink_hack(st_select_lex *select_lex)
+{
+ if (!select_stack_top) // Statements of the second type
+ {
+ if (!select_lex->get_master()->get_master())
+ ((st_select_lex *) select_lex->get_master())->
+ set_master(&builtin_select);
+ if (!builtin_select.get_slave())
+ builtin_select.set_slave(select_lex->get_master());
+ }
+}
+
+
+bool SELECT_LEX_UNIT::set_lock_to_the_last_select(Lex_select_lock l)
+{
+ if (l.defined_lock)
+ {
+ SELECT_LEX *sel= first_select();
+ while (sel->next_select())
+ sel= sel->next_select();
+ if (sel->braces)
+ {
+ my_error(ER_WRONG_USAGE, MYF(0), "lock options",
+ "SELECT in brackets");
+ return TRUE;
+ }
+ l.set_to(sel);
+ }
+ return FALSE;
+}
+
+/**
+ Generate unique name for generated derived table for this SELECT
+*/
+
+bool SELECT_LEX::make_unique_derived_name(THD *thd, LEX_CSTRING *alias)
+{
+ // uint32 digits + two underscores + trailing '\0'
+ char buff[MAX_INT_WIDTH + 2 + 1];
+ alias->length= my_snprintf(buff, sizeof(buff), "__%u", select_number);
+ alias->str= thd->strmake(buff, alias->length);
+ return !alias->str;
+}
+
+
+/*
+ Make a new sp_instr_stmt and set its m_query to a concatenation
+ of two strings.
+*/
+bool LEX::new_sp_instr_stmt(THD *thd,
+ const LEX_CSTRING &prefix,
+ const LEX_CSTRING &suffix)
+{
+ LEX_STRING qbuff;
+ sp_instr_stmt *i;
+
+ if (!(i= new (thd->mem_root) sp_instr_stmt(sphead->instructions(),
+ spcont, this)))
+ return true;
+
+ qbuff.length= prefix.length + suffix.length;
+ if (!(qbuff.str= (char*) alloc_root(thd->mem_root, qbuff.length + 1)))
+ return true;
+ if (prefix.length)
+ memcpy(qbuff.str, prefix.str, prefix.length);
+ strmake(qbuff.str + prefix.length, suffix.str, suffix.length);
+ i->m_query= qbuff;
+ return sphead->add_instr(i);
+}
+
+
+bool LEX::sp_proc_stmt_statement_finalize_buf(THD *thd, const LEX_CSTRING &qbuf)
+{
+ sphead->m_flags|= sp_get_flags_for_command(this);
+ /* "USE db" doesn't work in a procedure */
+ if (unlikely(sql_command == SQLCOM_CHANGE_DB))
+ {
+ my_error(ER_SP_BADSTATEMENT, MYF(0), "USE");
+ return true;
+ }
+ /*
+ Don't add an instruction for SET statements, since all
+ instructions for them were already added during processing
+ of "set" rule.
+ */
+ DBUG_ASSERT(sql_command != SQLCOM_SET_OPTION || var_list.is_empty());
+ if (sql_command != SQLCOM_SET_OPTION)
+ return new_sp_instr_stmt(thd, empty_clex_str, qbuf);
+ return false;
+}
+
+
+bool LEX::sp_proc_stmt_statement_finalize(THD *thd, bool no_lookahead)
+{
+ // Extract the query statement from the tokenizer
+ Lex_input_stream *lip= &thd->m_parser_state->m_lip;
+ Lex_cstring qbuf(sphead->m_tmp_query, no_lookahead ? lip->get_ptr() :
+ lip->get_tok_start());
+ return LEX::sp_proc_stmt_statement_finalize_buf(thd, qbuf);
+}
+
+
+/**
+ @brief
+ Extract the condition that can be pushed into WHERE clause
+
+ @param thd the thread handle
+ @param cond the condition from which to extract a pushed condition
+ @param remaining_cond IN/OUT the condition that will remain of cond after
+ the extraction
+ @param transformer the transformer callback function to be
+ applied to the fields of the condition so it
+ can be pushed`
+ @param arg parameter to be passed to the transformer
+
+ @details
+ This function builds the most restrictive condition depending only on
+ the fields used in the GROUP BY of this SELECT. These fields were
+ collected before in grouping_tmp_fields list of this SELECT.
+
+ First this method checks if this SELECT doesn't have any aggregation
+ functions and has no GROUP BY clause. If so cond can be entirely pushed
+ into WHERE.
+
+ Otherwise the method checks if there is a condition depending only on
+ grouping fields that can be extracted from cond.
+
+ The condition that can be pushed into WHERE should be transformed.
+ It is done by transformer.
+
+ The extracted condition is saved in cond_pushed_into_where of this select.
+ COND can remain not empty after the extraction of the conditions that can be
+ pushed into WHERE. It is saved in remaining_cond.
+
+ @note
+ This method is called for pushdown conditions into materialized
+ derived tables/views optimization.
+ Item::derived_field_transformer_for_where is passed as the actual
+ callback function.
+ Also it is called for pushdown into materialized IN subqueries.
+ Item::in_subq_field_transformer_for_where is passed as the actual
+ callback function.
+*/
+
+void st_select_lex::pushdown_cond_into_where_clause(THD *thd, Item *cond,
+ Item **remaining_cond,
+ Item_transformer transformer,
+ uchar *arg)
+{
+ if (!cond_pushdown_is_allowed())
+ return;
+ thd->lex->current_select= this;
+ if (have_window_funcs())
+ {
+ Item *cond_over_partition_fields;
+ check_cond_extraction_for_grouping_fields(thd, cond);
+ cond_over_partition_fields=
+ build_cond_for_grouping_fields(thd, cond, true);
+ if (cond_over_partition_fields)
+ cond_over_partition_fields= cond_over_partition_fields->transform(thd,
+ &Item::grouping_field_transformer_for_where,
+ (uchar*) this);
+ if (cond_over_partition_fields)
+ {
+ cond_over_partition_fields->walk(
+ &Item::cleanup_excluding_const_fields_processor, 0, 0);
+ cond_pushed_into_where= cond_over_partition_fields;
+ }
+
+ return;
+ }
+
+ if (!join->group_list && !with_sum_func)
+ {
+ cond= transform_condition_or_part(thd, cond, transformer, arg);
+ if (cond)
+ {
+ cond->walk(
+ &Item::cleanup_excluding_const_fields_processor, 0, 0);
+ cond_pushed_into_where= cond;
+ }
+
+ return;
+ }
+
+ /*
+ Figure out what can be extracted from cond and pushed into
+ the WHERE clause of this select.
+ */
+ Item *cond_over_grouping_fields;
+ check_cond_extraction_for_grouping_fields(thd, cond);
+ cond_over_grouping_fields=
+ build_cond_for_grouping_fields(thd, cond, true);
+
+ /*
+ Transform references to the columns of condition that can be pushed
+ into WHERE so it can be pushed.
+ */
+ if (cond_over_grouping_fields)
+ {
+ cond_over_grouping_fields=
+ transform_condition_or_part(thd, cond_over_grouping_fields,
+ &Item::grouping_field_transformer_for_where,
+ (uchar*) this);
+ }
+
+ if (cond_over_grouping_fields)
+ {
+
+ /*
+ Remove top conjuncts in cond that has been pushed into the WHERE
+ clause of this select
+ */
+ cond= remove_pushed_top_conjuncts(thd, cond);
+
+ cond_over_grouping_fields->walk(
+ &Item::cleanup_excluding_const_fields_processor, 0, 0);
+ cond_pushed_into_where= cond_over_grouping_fields;
+ }
+
+ *remaining_cond= cond;
+}
+
+
+/**
+ @brief
+ Mark OR-conditions as non-pushable to avoid repeatable pushdown
+
+ @param cond the processed condition
+
+ @details
+ Consider pushdown into the materialized derived table/view.
+ Consider OR condition that can be pushed into HAVING and some
+ parts of this OR condition that can be pushed into WHERE.
+
+ On example:
+
+ SELECT *
+ FROM t1,
+ (
+ SELECT a,MAX(c) AS m_c
+ GROUP BY a
+ ) AS dt
+ WHERE ((dt.m_c>10) AND (dt.a>2)) OR ((dt.m_c<7) and (dt.a<3)) AND
+ (t1.a=v1.a);
+
+
+ Here ((dt.m_c>10) AND (dt.a>2)) OR ((dt.m_c<7) and (dt.a<3)) or1
+ can be pushed down into the HAVING of the materialized
+ derived table dt.
+
+ (dt.a>2) OR (dt.a<3) part of or1 depends only on grouping fields
+ of dt and can be pushed into WHERE.
+
+ As a result:
+
+ SELECT *
+ FROM t1,
+ (
+ SELECT a,MAX(c) AS m_c
+ WHERE (dt.a>2) OR (dt.a<3)
+ GROUP BY a
+ HAVING ((dt.m_c>10) AND (dt.a>2)) OR ((dt.m_c<7) and (dt.a<3))
+ ) AS dt
+ WHERE ((dt.m_c>10) AND (dt.a>2)) OR ((dt.m_c<7) and (dt.a<3)) AND
+ (t1.a=v1.a);
+
+
+ Here (dt.a>2) OR (dt.a<3) also remains in HAVING of dt.
+ When SELECT that defines df is processed HAVING pushdown optimization
+ is made. In HAVING pushdown optimization it will extract
+ (dt.a>2) OR (dt.a<3) condition from or1 again and push it into WHERE.
+ This will cause duplicate conditions in WHERE of dt.
+
+ To avoid repeatable pushdown such OR conditions as or1 describen
+ above are marked with NO_EXTRACTION_FL.
+
+ @note
+ This method is called for pushdown into materialized
+ derived tables/views/IN subqueries optimization.
+*/
+
+void mark_or_conds_to_avoid_pushdown(Item *cond)
+{
+ if (cond->type() == Item::COND_ITEM &&
+ ((Item_cond*) cond)->functype() == Item_func::COND_AND_FUNC)
+ {
+ List_iterator<Item> li(*((Item_cond*) cond)->argument_list());
+ Item *item;
+ while ((item=li++))
+ {
+ if (item->type() == Item::COND_ITEM &&
+ ((Item_cond*) item)->functype() == Item_func::COND_OR_FUNC)
+ item->set_extraction_flag(NO_EXTRACTION_FL);
+ }
+ }
+ else if (cond->type() == Item::COND_ITEM &&
+ ((Item_cond*) cond)->functype() == Item_func::COND_OR_FUNC)
+ cond->set_extraction_flag(NO_EXTRACTION_FL);
+}
+
+/**
+ @brief
+ Get condition that can be pushed from HAVING into WHERE
+
+ @param thd the thread handle
+ @param cond the condition from which to extract the condition
+
+ @details
+ The method collects in attach_to_conds list conditions from cond
+ that can be pushed from HAVING into WHERE.
+
+ Conditions that can be pushed were marked with FULL_EXTRACTION_FL in
+ check_cond_extraction_for_grouping_fields() method.
+ Conditions that can't be pushed were marked with NO_EXTRACTION_FL.
+ Conditions which parts can be pushed weren't marked.
+
+ There are two types of conditions that can be pushed:
+ 1. Condition that can be simply moved from HAVING
+ (if cond is marked with FULL_EXTRACTION_FL or
+ cond is an AND condition and some of its parts are marked with
+ FULL_EXTRACTION_FL)
+ In this case condition is transformed and pushed into attach_to_conds
+ list.
+ 2. Part of some other condition c1 that can't be entirely pushed
+ (if с1 isn't marked with any flag).
+
+ For example:
+
+ SELECT t1.a,MAX(t1.b),t1.c
+ FROM t1
+ GROUP BY t1.a
+ HAVING ((t1.a > 5) AND (t1.c < 3)) OR (t1.a = 3);
+
+ Here (t1.a > 5) OR (t1.a = 3) from HAVING can be pushed into WHERE.
+
+ In this case build_pushable_cond() is called for c1.
+ This method builds a clone of the c1 part that can be pushed.
+
+ Transformation mentioned above is made with multiple_equality_transformer
+ transformer. It transforms all multiple equalities in the extracted
+ condition into the set of equalities.
+
+ @note
+ Conditions that can be pushed are collected in attach_to_conds in this way:
+ 1. if cond is an AND condition its parts that can be pushed into WHERE
+ are added to attach_to_conds list separately.
+ 2. in all other cases conditions are pushed into the list entirely.
+
+ @retval
+ true - if an error occurs
+ false - otherwise
+*/
+
+bool
+st_select_lex::build_pushable_cond_for_having_pushdown(THD *thd, Item *cond)
+{
+ List<Item> equalities;
+
+ /* Condition can't be pushed */
+ if (cond->get_extraction_flag() == NO_EXTRACTION_FL)
+ return false;
+
+ /**
+ Condition can be pushed entirely.
+ Transform its multiple equalities and add to attach_to_conds list.
+ */
+ if (cond->get_extraction_flag() == FULL_EXTRACTION_FL)
+ {
+ Item *result= cond->transform(thd,
+ &Item::multiple_equality_transformer,
+ (uchar *)this);
+ if (!result)
+ return true;
+ if (result->type() == Item::COND_ITEM &&
+ ((Item_cond*) result)->functype() == Item_func::COND_AND_FUNC)
+ {
+ List_iterator<Item> li(*((Item_cond*) result)->argument_list());
+ Item *item;
+ while ((item= li++))
+ {
+ if (attach_to_conds.push_back(item, thd->mem_root))
+ return true;
+ }
+ }
+ else
+ {
+ if (attach_to_conds.push_back(result, thd->mem_root))
+ return true;
+ }
+ return false;
+ }
+
+ /**
+ There is no flag set for this condition. It means that some
+ part of this condition can be pushed.
+ */
+ if (cond->type() != Item::COND_ITEM)
+ return false;
+
+ if (((Item_cond *)cond)->functype() != Item_cond::COND_AND_FUNC)
+ {
+ /*
+ cond is not a conjunctive formula and it cannot be pushed into WHERE.
+ Try to extract a formula that can be pushed.
+ */
+ Item *fix= cond->build_pushable_cond(thd, 0, 0);
+ if (!fix)
+ return false;
+ if (attach_to_conds.push_back(fix, thd->mem_root))
+ return true;
+ }
+ else
+ {
+ List_iterator<Item> li(*((Item_cond*) cond)->argument_list());
+ Item *item;
+ while ((item=li++))
+ {
+ if (item->get_extraction_flag() == NO_EXTRACTION_FL)
+ continue;
+ else if (item->get_extraction_flag() == FULL_EXTRACTION_FL)
+ {
+ Item *result= item->transform(thd,
+ &Item::multiple_equality_transformer,
+ (uchar *)item);
+ if (!result)
+ return true;
+ if (result->type() == Item::COND_ITEM &&
+ ((Item_cond*) result)->functype() == Item_func::COND_AND_FUNC)
+ {
+ List_iterator<Item> li(*((Item_cond*) result)->argument_list());
+ Item *item;
+ while ((item=li++))
+ {
+ if (attach_to_conds.push_back(item, thd->mem_root))
+ return true;
+ }
+ }
+ else
+ {
+ if (attach_to_conds.push_back(result, thd->mem_root))
+ return true;
+ }
+ }
+ else
+ {
+ Item *fix= item->build_pushable_cond(thd, 0, 0);
+ if (!fix)
+ continue;
+ if (attach_to_conds.push_back(fix, thd->mem_root))
+ return true;
+ }
+ }
+ }
+ return false;
+}
+
+
+/**
+ Check if item is equal to some field in Field_pair 'field_pair'
+ from 'pair_list' and return found 'field_pair' if it exists.
+*/
+
+Field_pair *get_corresponding_field_pair(Item *item,
+ List<Field_pair> pair_list)
+{
+ DBUG_ASSERT(item->type() == Item::FIELD_ITEM ||
+ (item->type() == Item::REF_ITEM &&
+ ((((Item_ref *) item)->ref_type() == Item_ref::VIEW_REF) ||
+ (((Item_ref *) item)->ref_type() == Item_ref::REF))));
+
+ List_iterator<Field_pair> it(pair_list);
+ Field_pair *field_pair;
+ Item_field *field_item= (Item_field *) (item->real_item());
+ while ((field_pair= it++))
+ {
+ if (field_item->field == field_pair->field)
+ return field_pair;
+ }
+ return NULL;
+}
+
+
+/**
+ @brief
+ Collect fields from multiple equalities which are equal to grouping
+
+ @param thd the thread handle
+
+ @details
+ This method checks if multiple equalities of the WHERE clause contain
+ fields from GROUP BY of this SELECT. If so all fields of such multiple
+ equalities are collected in grouping_tmp_fields list without repetitions.
+
+ @retval
+ true - if an error occurs
+ false - otherwise
+*/
+
+bool st_select_lex::collect_fields_equal_to_grouping(THD *thd)
+{
+ if (!join->cond_equal || join->cond_equal->is_empty())
+ return false;
+
+ List_iterator_fast<Item_equal> li(join->cond_equal->current_level);
+ Item_equal *item_equal;
+
+ while ((item_equal= li++))
+ {
+ Item_equal_fields_iterator it(*item_equal);
+ Item *item;
+ while ((item= it++))
+ {
+ if (get_corresponding_field_pair(item, grouping_tmp_fields))
+ break;
+ }
+ if (!item)
+ break;
+
+ it.rewind();
+ while ((item= it++))
+ {
+ if (get_corresponding_field_pair(item, grouping_tmp_fields))
+ continue;
+ Field_pair *grouping_tmp_field=
+ new Field_pair(((Item_field *)item->real_item())->field, item);
+ if (grouping_tmp_fields.push_back(grouping_tmp_field, thd->mem_root))
+ return true;
+ }
+ }
+ return false;
+}
+
+
+/**
+ @brief
+ Remove marked top conjuncts of HAVING for having pushdown
+
+ @param thd the thread handle
+ @param cond the condition which subformulas are to be removed
+
+ @details
+ This method removes from cond all subformulas that can be moved from HAVING
+ into WHERE.
+
+ @retval
+ condition without removed subformulas
+ 0 if the whole 'cond' is removed
+*/
+
+Item *remove_pushed_top_conjuncts_for_having(THD *thd, Item *cond)
+{
+ /* Nothing to extract */
+ if (cond->get_extraction_flag() == NO_EXTRACTION_FL)
+ {
+ cond->clear_extraction_flag();
+ return cond;
+ }
+ /* cond can be pushed in WHERE entirely */
+ if (cond->get_extraction_flag() == FULL_EXTRACTION_FL)
+ {
+ cond->clear_extraction_flag();
+ return 0;
+ }
+
+ /* Some parts of cond can be pushed */
+ if (cond->type() == Item::COND_ITEM &&
+ ((Item_cond*) cond)->functype() == Item_func::COND_AND_FUNC)
+ {
+ List_iterator<Item> li(*((Item_cond*) cond)->argument_list());
+ Item *item;
+ while ((item=li++))
+ {
+ if (item->get_extraction_flag() == NO_EXTRACTION_FL)
+ item->clear_extraction_flag();
+ else if (item->get_extraction_flag() == FULL_EXTRACTION_FL)
+ {
+ if (item->type() == Item::FUNC_ITEM &&
+ ((Item_func*) item)->functype() == Item_func::MULT_EQUAL_FUNC)
+ item->set_extraction_flag(DELETION_FL);
+ else
+ {
+ item->clear_extraction_flag();
+ li.remove();
+ }
+ }
+ }
+ switch (((Item_cond*) cond)->argument_list()->elements)
+ {
+ case 0:
+ return 0;
+ case 1:
+ return (((Item_cond*) cond)->argument_list()->head());
+ default:
+ return cond;
+ }
+ }
+ return cond;
+}
+
+
+/**
+ @brief
+ Extract condition that can be pushed from HAVING into WHERE
+
+ @param thd the thread handle
+ @param having the HAVING clause of this select
+ @param having_equal multiple equalities of HAVING
+
+ @details
+ This method builds a set of conditions dependent only on
+ fields used in the GROUP BY of this select (directly or indirectly
+ through equalities). These conditions are extracted from the HAVING
+ clause of this select.
+ The method saves these conditions into attach_to_conds list and removes
+ from HAVING conditions that can be entirely pushed into WHERE.
+
+ Example of the HAVING pushdown transformation:
+
+ SELECT t1.a,MAX(t1.b)
+ FROM t1
+ GROUP BY t1.a
+ HAVING (t1.a>2) AND (MAX(c)>12);
+
+ =>
+
+ SELECT t1.a,MAX(t1.b)
+ FROM t1
+ WHERE (t1.a>2)
+ GROUP BY t1.a
+ HAVING (MAX(c)>12);
+
+ In this method (t1.a>2) is not attached to the WHERE clause.
+ It is pushed into the attach_to_conds list to be attached to
+ the WHERE clause later.
+
+ In details:
+ 1. Collect fields used in the GROUP BY grouping_fields of this SELECT
+ 2. Collect fields equal to grouping_fields from the WHERE clause
+ of this SELECT and add them to the grouping_fields list.
+ 3. Extract the most restrictive condition from the HAVING clause of this
+ select that depends only on the grouping fields (directly or indirectly
+ through equality).
+ If the extracted condition is an AND condition it is transformed into a
+ list of all its conjuncts saved in attach_to_conds. Otherwise,
+ the condition is put into attach_to_conds as the only its element.
+ 4. Remove conditions from HAVING clause that can be entirely pushed
+ into WHERE.
+ Multiple equalities are not removed but marked with DELETION_FL flag.
+ They will be deleted later in substitite_for_best_equal_field() called
+ for the HAVING condition.
+ 5. Unwrap fields wrapped in Item_ref wrappers contained in the condition
+ of attach_to_conds so the condition could be pushed into WHERE.
+
+ @note
+ This method is similar to st_select_lex::pushdown_cond_into_where_clause().
+
+ @retval TRUE if an error occurs
+ @retval FALSE otherwise
+*/
+
+Item *st_select_lex::pushdown_from_having_into_where(THD *thd, Item *having)
+{
+ if (!having || !group_list.first)
+ return having;
+ if (!cond_pushdown_is_allowed())
+ return having;
+
+ st_select_lex *save_curr_select= thd->lex->current_select;
+ thd->lex->current_select= this;
+
+ /*
+ 1. Collect fields used in the GROUP BY grouping fields of this SELECT
+ 2. Collect fields equal to grouping_fields from the WHERE clause
+ of this SELECT and add them to the grouping fields list.
+ */
+ if (collect_grouping_fields(thd) ||
+ collect_fields_equal_to_grouping(thd))
+ return having;
+
+ /*
+ 3. Extract the most restrictive condition from the HAVING clause of this
+ select that depends only on the grouping fields (directly or indirectly
+ through equality).
+ If the extracted condition is an AND condition it is transformed into a
+ list of all its conjuncts saved in attach_to_conds. Otherwise,
+ the condition is put into attach_to_conds as the only its element.
+ */
+ List_iterator_fast<Item> it(attach_to_conds);
+ Item *item;
+ check_cond_extraction_for_grouping_fields(thd, having);
+ if (build_pushable_cond_for_having_pushdown(thd, having))
+ {
+ attach_to_conds.empty();
+ goto exit;
+ }
+ if (!attach_to_conds.elements)
+ goto exit;
+
+ /*
+ 4. Remove conditions from HAVING clause that can be entirely pushed
+ into WHERE.
+ Multiple equalities are not removed but marked with DELETION_FL flag.
+ They will be deleted later in substitite_for_best_equal_field() called
+ for the HAVING condition.
+ */
+ having= remove_pushed_top_conjuncts_for_having(thd, having);
+
+ /*
+ Change join->cond_equal which points to the multiple equalities of
+ the top level of HAVING.
+ Removal of AND conditions may leave only one conjunct in HAVING.
+
+ Example 1:
+ SELECT *
+ FROM t1
+ GROUP BY t1.a
+ (t1.a < 2) AND (t1.b = 2)
+
+ (t1.a < 2) is pushed into WHERE.
+ join->cond_equal should point on (t1.b = 2) multiple equality now.
+
+ Example 2:
+ SELECT *
+ FROM t1
+ GROUP BY t1.a
+ (t1.a = 2) AND (t1.b < 2)
+
+ (t1.a = 2) is pushed into WHERE.
+ join->cond_equal should be NULL now.
+ */
+ if (having &&
+ having->type() == Item::FUNC_ITEM &&
+ ((Item_func*) having)->functype() == Item_func::MULT_EQUAL_FUNC)
+ join->having_equal= new (thd->mem_root) COND_EQUAL((Item_equal *)having,
+ thd->mem_root);
+ else if (!having ||
+ having->type() != Item::COND_ITEM ||
+ ((Item_cond *)having)->functype() != Item_cond::COND_AND_FUNC)
+ join->having_equal= 0;
+
+ /*
+ 5. Unwrap fields wrapped in Item_ref wrappers contained in the condition
+ of attach_to_conds so the condition could be pushed into WHERE.
+ */
+ it.rewind();
+ while ((item=it++))
+ {
+ item= item->transform(thd,
+ &Item::field_transformer_for_having_pushdown,
+ (uchar *)this);
+
+ if (item->walk(&Item::cleanup_excluding_immutables_processor, 0, STOP_PTR)
+ || item->fix_fields(thd, NULL))
+ {
+ attach_to_conds.empty();
+ goto exit;
+ }
+ }
+exit:
+ thd->lex->current_select= save_curr_select;
+ return having;
+}
+
+
+bool LEX::stmt_install_plugin(const DDL_options_st &opt,
+ const Lex_ident_sys_st &name,
+ const LEX_CSTRING &soname)
+{
+ create_info.init();
+ if (add_create_options_with_check(opt))
+ return true;
+ sql_command= SQLCOM_INSTALL_PLUGIN;
+ comment= name;
+ ident= soname;
+ return false;
+}
+
+
+void LEX::stmt_install_plugin(const LEX_CSTRING &soname)
+{
+ sql_command= SQLCOM_INSTALL_PLUGIN;
+ comment= null_clex_str;
+ ident= soname;
+}
+
+
+bool LEX::stmt_uninstall_plugin_by_name(const DDL_options_st &opt,
+ const Lex_ident_sys_st &name)
+{
+ check_opt.init();
+ if (add_create_options_with_check(opt))
+ return true;
+ sql_command= SQLCOM_UNINSTALL_PLUGIN;
+ comment= name;
+ ident= null_clex_str;
+ return false;
+}
+
+
+bool LEX::stmt_uninstall_plugin_by_soname(const DDL_options_st &opt,
+ const LEX_CSTRING &soname)
+{
+ check_opt.init();
+ if (add_create_options_with_check(opt))
+ return true;
+ sql_command= SQLCOM_UNINSTALL_PLUGIN;
+ comment= null_clex_str;
+ ident= soname;
+ return false;
+}
+
+
+bool LEX::stmt_prepare_validate(const char *stmt_type)
+{
+ if (unlikely(table_or_sp_used()))
+ {
+ my_error(ER_SUBQUERIES_NOT_SUPPORTED, MYF(0), stmt_type);
+ return true;
+ }
+ return check_main_unit_semantics();
+}
+
+
+bool LEX::stmt_prepare(const Lex_ident_sys_st &ident, Item *code)
+{
+ sql_command= SQLCOM_PREPARE;
+ if (stmt_prepare_validate("PREPARE..FROM"))
+ return true;
+ prepared_stmt.set(ident, code, NULL);
+ return false;
+}
+
+
+bool LEX::stmt_execute_immediate(Item *code, List<Item> *params)
+{
+ sql_command= SQLCOM_EXECUTE_IMMEDIATE;
+ if (stmt_prepare_validate("EXECUTE IMMEDIATE"))
+ return true;
+ static const Lex_ident_sys immediate(STRING_WITH_LEN("IMMEDIATE"));
+ prepared_stmt.set(immediate, code, params);
+ return false;
+}
+
+
+bool LEX::stmt_execute(const Lex_ident_sys_st &ident, List<Item> *params)
+{
+ sql_command= SQLCOM_EXECUTE;
+ prepared_stmt.set(ident, NULL, params);
+ return stmt_prepare_validate("EXECUTE..USING");
+}
+
+
+void LEX::stmt_deallocate_prepare(const Lex_ident_sys_st &ident)
+{
+ sql_command= SQLCOM_DEALLOCATE_PREPARE;
+ prepared_stmt.set(ident, NULL, NULL);
+}
+
+
+bool LEX::stmt_alter_table_exchange_partition(Table_ident *table)
+{
+ DBUG_ASSERT(sql_command == SQLCOM_ALTER_TABLE);
+ first_select_lex()->db= table->db;
+ if (first_select_lex()->db.str == NULL &&
+ copy_db_to(&first_select_lex()->db))
+ return true;
+ name= table->table;
+ alter_info.partition_flags|= ALTER_PARTITION_EXCHANGE;
+ if (!first_select_lex()->add_table_to_list(thd, table, NULL,
+ TL_OPTION_UPDATING,
+ TL_READ_NO_INSERT,
+ MDL_SHARED_NO_WRITE))
+ return true;
+ DBUG_ASSERT(!m_sql_cmd);
+ m_sql_cmd= new (thd->mem_root) Sql_cmd_alter_table_exchange_partition();
+ return m_sql_cmd == NULL;
+}
+
+
+void LEX::stmt_purge_to(const LEX_CSTRING &to)
+{
+ type= 0;
+ sql_command= SQLCOM_PURGE;
+ to_log= to.str;
+}
+
+
+bool LEX::stmt_purge_before(Item *item)
+{
+ type= 0;
+ sql_command= SQLCOM_PURGE_BEFORE;
+ value_list.empty();
+ value_list.push_front(item, thd->mem_root);
+ return check_main_unit_semantics();
+}
+
+
+bool LEX::stmt_create_udf_function(const DDL_options_st &options,
+ enum_sp_aggregate_type agg_type,
+ const Lex_ident_sys_st &name,
+ Item_result return_type,
+ const LEX_CSTRING &soname)
+{
+ if (stmt_create_function_start(options))
+ return true;
+
+ if (unlikely(is_native_function(thd, &name)))
+ {
+ my_error(ER_NATIVE_FCT_NAME_COLLISION, MYF(0), name.str);
+ return true;
+ }
+ sql_command= SQLCOM_CREATE_FUNCTION;
+ udf.name= name;
+ udf.returns= return_type;
+ udf.dl= soname.str;
+ udf.type= agg_type == GROUP_AGGREGATE ? UDFTYPE_AGGREGATE :
+ UDFTYPE_FUNCTION;
+ stmt_create_routine_finalize();
+ return false;
+}
+
+
+bool LEX::stmt_create_stored_function_start(const DDL_options_st &options,
+ enum_sp_aggregate_type agg_type,
+ const sp_name *spname)
+{
+ if (stmt_create_function_start(options) ||
+ unlikely(!make_sp_head_no_recursive(thd, spname,
+ &sp_handler_function, agg_type)))
+ return true;
+ return false;
+}
+
+
+bool LEX::stmt_drop_function(const DDL_options_st &options,
+ const Lex_ident_sys_st &db,
+ const Lex_ident_sys_st &name)
+{
+ if (unlikely(db.str && check_db_name((LEX_STRING*) &db)))
+ {
+ my_error(ER_WRONG_DB_NAME, MYF(0), db.str);
+ return true;
+ }
+ if (unlikely(sphead))
+ {
+ my_error(ER_SP_NO_DROP_SP, MYF(0), "FUNCTION");
+ return true;
+ }
+ set_command(SQLCOM_DROP_FUNCTION, options);
+ spname= new (thd->mem_root) sp_name(&db, &name, true);
+ return spname == NULL;
+}
+
+
+bool LEX::stmt_drop_function(const DDL_options_st &options,
+ const Lex_ident_sys_st &name)
+{
+ LEX_CSTRING db= {0, 0};
+ if (unlikely(sphead))
+ {
+ my_error(ER_SP_NO_DROP_SP, MYF(0), "FUNCTION");
+ return true;
+ }
+ if (thd->db.str && unlikely(copy_db_to(&db)))
+ return true;
+ set_command(SQLCOM_DROP_FUNCTION, options);
+ spname= new (thd->mem_root) sp_name(&db, &name, false);
+ return spname == NULL;
+}
+
+
+bool LEX::stmt_drop_procedure(const DDL_options_st &options,
+ sp_name *name)
+{
+ if (unlikely(sphead))
+ {
+ my_error(ER_SP_NO_DROP_SP, MYF(0), "PROCEDURE");
+ return true;
+ }
+ set_command(SQLCOM_DROP_PROCEDURE, options);
+ spname= name;
+ return false;
+}
+
+
+bool LEX::stmt_alter_function_start(sp_name *name)
+{
+ if (unlikely(sphead))
+ {
+ my_error(ER_SP_NO_DROP_SP, MYF(0), "FUNCTION");
+ return true;
+ }
+ if (main_select_push())
+ return true;
+ sp_chistics.init();
+ sql_command= SQLCOM_ALTER_FUNCTION;
+ spname= name;
+ return false;
+}
+
+
+bool LEX::stmt_alter_procedure_start(sp_name *name)
+{
+ if (unlikely(sphead))
+ {
+ my_error(ER_SP_NO_DROP_SP, MYF(0), "PROCEDURE");
+ return true;
+ }
+ if (main_select_push())
+ return true;
+ sp_chistics.init();
+ sql_command= SQLCOM_ALTER_PROCEDURE;
+ spname= name;
+ return false;
+}
+
+
+Spvar_definition *LEX::row_field_name(THD *thd, const Lex_ident_sys_st &name)
+{
+ Spvar_definition *res;
+ if (unlikely(check_string_char_length(&name, 0, NAME_CHAR_LEN,
+ system_charset_info, 1)))
+ {
+ my_error(ER_TOO_LONG_IDENT, MYF(0), name.str);
+ return NULL;
+ }
+ if (unlikely(!(res= new (thd->mem_root) Spvar_definition())))
+ return NULL;
+ init_last_field(res, &name, thd->variables.collation_database);
+ return res;
+}
+
+
+Item *
+Lex_cast_type_st::create_typecast_item_or_error(THD *thd, Item *item,
+ CHARSET_INFO *cs) const
+{
+ Item *tmp= create_typecast_item(thd, item, cs);
+ if (!tmp)
+ {
+ Name name= m_type_handler->name();
+ char buf[128];
+ size_t length= my_snprintf(buf, sizeof(buf), "CAST(expr AS %.*s)",
+ (int) name.length(), name.ptr());
+ my_error(ER_UNKNOWN_OPERATOR, MYF(0),
+ ErrConvString(buf, length, system_charset_info).ptr());
+ }
+ return tmp;
+}
+
+
+void Lex_field_type_st::set_handler_length_flags(const Type_handler *handler,
+ const char *length,
+ uint32 flags)
+{
+ DBUG_ASSERT(!handler->is_unsigned());
+ if (flags & UNSIGNED_FLAG)
+ handler= handler->type_handler_unsigned();
+ set(handler, length, NULL);
+}
+
+
+bool LEX::set_field_type_udt(Lex_field_type_st *type,
+ const LEX_CSTRING &name,
+ const Lex_length_and_dec_st &attr)
+{
+ const Type_handler *h;
+ if (!(h= Type_handler::handler_by_name_or_error(thd, name)))
+ return true;
+ type->set(h, attr);
+ charset= &my_charset_bin;
+ return false;
+}
+
+
+bool LEX::set_cast_type_udt(Lex_cast_type_st *type,
+ const LEX_CSTRING &name)
+{
+ const Type_handler *h;
+ if (!(h= Type_handler::handler_by_name_or_error(thd, name)))
+ return true;
+ type->set(h);
+ charset= NULL;
+ return false;
+}
+
+
+bool sp_expr_lex::sp_repeat_loop_finalize(THD *thd)
+{
+ uint ip= sphead->instructions();
+ sp_label *lab= spcont->last_label(); /* Jumping back */
+ sp_instr_jump_if_not *i= new (thd->mem_root)
+ sp_instr_jump_if_not(ip, spcont, get_item(), lab->ip, this);
+ if (unlikely(i == NULL) ||
+ unlikely(sphead->add_instr(i)))
+ return true;
+ /* We can shortcut the cont_backpatch here */
+ i->m_cont_dest= ip+1;
+ return false;
+}
+
+
+bool sp_expr_lex::sp_if_expr(THD *thd)
+{
+ uint ip= sphead->instructions();
+ sp_instr_jump_if_not *i= new (thd->mem_root)
+ sp_instr_jump_if_not(ip, spcont, get_item(), this);
+ return
+ (unlikely(i == NULL) ||
+ unlikely(sphead->push_backpatch(thd, i,
+ spcont->push_label(thd, &empty_clex_str,
+ 0))) ||
+ unlikely(sphead->add_cont_backpatch(i)) ||
+ unlikely(sphead->add_instr(i)));
+}
+
+
+bool LEX::sp_if_after_statements(THD *thd)
+{
+ uint ip= sphead->instructions();
+ sp_instr_jump *i= new (thd->mem_root) sp_instr_jump(ip, spcont);
+ if (unlikely(i == NULL) ||
+ unlikely(sphead->add_instr(i)))
+ return true;
+ sphead->backpatch(spcont->pop_label());
+ sphead->push_backpatch(thd, i, spcont->push_label(thd, &empty_clex_str, 0));
+ return false;
+}
+
+
+sp_condition_value *LEX::stmt_signal_value(const Lex_ident_sys_st &ident)
+{
+ sp_condition_value *cond;
+ /* SIGNAL foo cannot be used outside of stored programs */
+ if (unlikely(spcont == NULL))
+ {
+ my_error(ER_SP_COND_MISMATCH, MYF(0), ident.str);
+ return NULL;
+ }
+ cond= spcont->find_declared_or_predefined_condition(thd, &ident);
+ if (unlikely(cond == NULL))
+ {
+ my_error(ER_SP_COND_MISMATCH, MYF(0), ident.str);
+ return NULL;
+ }
+ bool bad= thd->variables.sql_mode & MODE_ORACLE ?
+ !cond->has_sql_state() :
+ cond->type != sp_condition_value::SQLSTATE;
+ if (unlikely(bad))
+ {
+ my_error(ER_SIGNAL_BAD_CONDITION_TYPE, MYF(0));
+ return NULL;
+ }
+ return cond;
+}
+
+
+bool LEX::add_table_foreign_key(const LEX_CSTRING *name,
+ const LEX_CSTRING *constraint_name,
+ Table_ident *ref_table_name,
+ DDL_options ddl_options)
+{
+ Key *key= new (thd->mem_root) Foreign_key(name,
+ &last_key->columns,
+ constraint_name,
+ &ref_table_name->db,
+ &ref_table_name->table,
+ &ref_list,
+ fk_delete_opt,
+ fk_update_opt,
+ fk_match_option,
+ ddl_options);
+ if (unlikely(key == NULL))
+ return true;
+
+ /*
+ handle_if_exists_options() expects the two keys in this order:
+ the Foreign_key, followed by its auto-generated Key.
+ */
+ alter_info.key_list.push_back(key, thd->mem_root);
+ alter_info.key_list.push_back(last_key, thd->mem_root);
+
+ option_list= NULL;
+
+ /* Only used for ALTER TABLE. Ignored otherwise. */
+ alter_info.flags|= ALTER_ADD_FOREIGN_KEY;
+
+ return false;
+}
+
+
+bool LEX::add_column_foreign_key(const LEX_CSTRING *name,
+ const LEX_CSTRING *constraint_name,
+ Table_ident *ref_table_name,
+ DDL_options ddl_options)
+{
+ if (last_field->vcol_info || last_field->vers_sys_field())
+ {
+ thd->parse_error();
+ return true;
+ }
+ if (unlikely(!(last_key= (new (thd->mem_root)
+ Key(Key::MULTIPLE, constraint_name,
+ HA_KEY_ALG_UNDEF, true, ddl_options)))))
+ return true;
+ Key_part_spec *key= new (thd->mem_root) Key_part_spec(name, 0);
+ if (unlikely(key == NULL))
+ return true;
+ last_key->columns.push_back(key, thd->mem_root);
+ if (ref_list.is_empty())
+ {
+ ref_list.push_back(key, thd->mem_root);
+ }
+ if (unlikely(add_table_foreign_key(constraint_name, constraint_name,
+ ref_table_name, ddl_options)))
+ return true;
+ option_list= NULL;
+
+ /* Only used for ALTER TABLE. Ignored otherwise. */
+ alter_info.flags|= ALTER_ADD_FOREIGN_KEY;
+
+ return false;
+}
+
+
+bool LEX::stmt_grant_table(THD *thd,
+ Grant_privilege *grant,
+ const Lex_grant_object_name &ident,
+ privilege_t grant_option)
+{
+ sql_command= SQLCOM_GRANT;
+ return
+ grant->set_object_name(thd, ident, current_select, grant_option) ||
+ !(m_sql_cmd= new (thd->mem_root) Sql_cmd_grant_table(sql_command, *grant));
+}
+
+
+bool LEX::stmt_revoke_table(THD *thd,
+ Grant_privilege *grant,
+ const Lex_grant_object_name &ident)
+{
+ sql_command= SQLCOM_REVOKE;
+ return
+ grant->set_object_name(thd, ident, current_select, NO_ACL) ||
+ !(m_sql_cmd= new (thd->mem_root) Sql_cmd_grant_table(sql_command, *grant));
+}
+
+
+bool LEX::stmt_grant_sp(THD *thd,
+ Grant_privilege *grant,
+ const Lex_grant_object_name &ident,
+ const Sp_handler &sph,
+ privilege_t grant_option)
+{
+ sql_command= SQLCOM_GRANT;
+ return
+ grant->set_object_name(thd, ident, current_select, grant_option) ||
+ add_grant_command(thd, grant->columns()) ||
+ !(m_sql_cmd= new (thd->mem_root) Sql_cmd_grant_sp(sql_command,
+ *grant, sph));
+}
+
+
+bool LEX::stmt_revoke_sp(THD *thd,
+ Grant_privilege *grant,
+ const Lex_grant_object_name &ident,
+ const Sp_handler &sph)
+{
+ sql_command= SQLCOM_REVOKE;
+ return
+ grant->set_object_name(thd, ident, current_select, NO_ACL) ||
+ add_grant_command(thd, grant->columns()) ||
+ !(m_sql_cmd= new (thd->mem_root) Sql_cmd_grant_sp(sql_command,
+ *grant, sph));
+}
+
+
+bool LEX::stmt_grant_proxy(THD *thd, LEX_USER *user, privilege_t grant_option)
+{
+ users_list.push_front(user);
+ sql_command= SQLCOM_GRANT;
+ return !(m_sql_cmd= new (thd->mem_root) Sql_cmd_grant_proxy(sql_command,
+ grant_option));
+}
+
+
+bool LEX::stmt_revoke_proxy(THD *thd, LEX_USER *user)
+{
+ users_list.push_front(user);
+ sql_command= SQLCOM_REVOKE;
+ return !(m_sql_cmd= new (thd->mem_root) Sql_cmd_grant_proxy(sql_command,
+ NO_ACL));
+}
+
+
+LEX_USER *LEX::current_user_for_set_password(THD *thd)
+{
+ LEX_CSTRING pw= { STRING_WITH_LEN("password") };
+ if (unlikely(spcont && spcont->find_variable(&pw, false)))
+ {
+ my_error(ER_SP_BAD_VAR_SHADOW, MYF(0), pw.str);
+ return NULL;
+ }
+ LEX_USER *res;
+ if (unlikely(!(res= (LEX_USER*) thd->calloc(sizeof(LEX_USER)))))
+ return NULL;
+ res->user= current_user;
+ return res;
+}
+
+
+bool LEX::sp_create_set_password_instr(THD *thd,
+ LEX_USER *user,
+ USER_AUTH *auth,
+ bool no_lookahead)
+{
+ user->auth= auth;
+ set_var_password *var= new (thd->mem_root) set_var_password(user);
+ if (unlikely(var == NULL) ||
+ unlikely(var_list.push_back(var, thd->mem_root)))
+ return true;
+ autocommit= true;
+ if (sphead)
+ sphead->m_flags|= sp_head::HAS_SET_AUTOCOMMIT_STMT;
+ return sp_create_assignment_instr(thd, no_lookahead);
+}
+
+
+bool LEX::map_data_type(const Lex_ident_sys_st &schema_name,
+ Lex_field_type_st *type) const
+{
+ const Schema *schema= schema_name.str ?
+ Schema::find_by_name(schema_name) :
+ Schema::find_implied(thd);
+ if (!schema)
+ {
+ char buf[128];
+ const Name type_name= type->type_handler()->name();
+ my_snprintf(buf, sizeof(buf), "%.*s.%.*s",
+ (int) schema_name.length, schema_name.str,
+ (int) type_name.length(), type_name.ptr());
+ my_error(ER_UNKNOWN_DATA_TYPE, MYF(0), buf);
+ return true;
+ }
+ const Type_handler *mapped= schema->map_data_type(thd, type->type_handler());
+ type->set_handler(mapped);
+ return false;
+}
+
+
+bool SELECT_LEX_UNIT::explainable() const
+{
+ /*
+ EXPLAIN/ANALYZE unit, when:
+ (1) if it's a subquery - it's not part of eliminated WHERE/ON clause.
+ (2) if it's a CTE - it's not hanging (needed for execution)
+ (3) if it's a derived - it's not merged
+ if it's not 1/2/3 - it's some weird internal thing, ignore it
+ */
+ return item ?
+ !item->eliminated : // (1)
+ with_element ?
+ derived && derived->derived_result &&
+ !with_element->is_hanging_recursive(): // (2)
+ derived ?
+ derived->is_materialized_derived() : // (3)
+ false;
+}