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|
/* -*- C++ -*- */
/*
Copyright (c) 2002, 2011, Oracle and/or its affiliates.
Copyright (c) 2020, MariaDB
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1335 USA */
#ifndef _SP_HEAD_H_
#define _SP_HEAD_H_
#ifdef USE_PRAGMA_INTERFACE
#pragma interface /* gcc class implementation */
#endif
/*
It is necessary to include set_var.h instead of item.h because there
are dependencies on include order for set_var.h and item.h. This
will be resolved later.
*/
#include "sql_class.h" // THD, set_var.h: THD
#include "set_var.h" // Item
#include "sp_pcontext.h" // sp_pcontext
#include <stddef.h>
#include "sp.h"
/**
@defgroup Stored_Routines Stored Routines
@ingroup Runtime_Environment
@{
*/
uint
sp_get_flags_for_command(LEX *lex);
class sp_instr;
class sp_instr_opt_meta;
class sp_instr_jump_if_not;
/*************************************************************************/
/**
Stored_program_creation_ctx -- base class for creation context of stored
programs (stored routines, triggers, events).
*/
class Stored_program_creation_ctx :public Default_object_creation_ctx
{
public:
CHARSET_INFO *get_db_cl()
{
return m_db_cl;
}
public:
virtual Stored_program_creation_ctx *clone(MEM_ROOT *mem_root) = 0;
protected:
Stored_program_creation_ctx(THD *thd)
: Default_object_creation_ctx(thd),
m_db_cl(thd->variables.collation_database)
{ }
Stored_program_creation_ctx(CHARSET_INFO *client_cs,
CHARSET_INFO *connection_cl,
CHARSET_INFO *db_cl)
: Default_object_creation_ctx(client_cs, connection_cl),
m_db_cl(db_cl)
{ }
protected:
virtual void change_env(THD *thd) const
{
thd->variables.collation_database= m_db_cl;
Default_object_creation_ctx::change_env(thd);
}
protected:
/**
db_cl stores the value of the database collation. Both character set
and collation attributes are used.
Database collation is included into the context because it defines the
default collation for stored-program variables.
*/
CHARSET_INFO *m_db_cl;
};
/*************************************************************************/
class sp_name : public Sql_alloc,
public Database_qualified_name
{
public:
bool m_explicit_name; /**< Prepend the db name? */
sp_name(const LEX_CSTRING *db, const LEX_CSTRING *name,
bool use_explicit_name)
: Database_qualified_name(db, name), m_explicit_name(use_explicit_name)
{
if (lower_case_table_names && m_db.str)
m_db.length= my_casedn_str(files_charset_info, (char*) m_db.str);
}
/** Create temporary sp_name object from MDL key. Store in qname_buff */
sp_name(const MDL_key *key, char *qname_buff);
~sp_name()
{}
};
bool
check_routine_name(const LEX_CSTRING *ident);
class sp_head :private Query_arena,
public Database_qualified_name,
public Sql_alloc
{
sp_head(const sp_head &)= delete;
void operator=(sp_head &)= delete;
protected:
MEM_ROOT main_mem_root;
public:
/** Possible values of m_flags */
enum {
HAS_RETURN= 1, // For FUNCTIONs only: is set if has RETURN
MULTI_RESULTS= 8, // Is set if a procedure with SELECT(s)
CONTAINS_DYNAMIC_SQL= 16, // Is set if a procedure with PREPARE/EXECUTE
IS_INVOKED= 32, // Is set if this sp_head is being used
HAS_SET_AUTOCOMMIT_STMT= 64,// Is set if a procedure with 'set autocommit'
/* Is set if a procedure with COMMIT (implicit or explicit) | ROLLBACK */
HAS_COMMIT_OR_ROLLBACK= 128,
LOG_SLOW_STATEMENTS= 256, // Used by events
LOG_GENERAL_LOG= 512, // Used by events
HAS_SQLCOM_RESET= 1024,
HAS_SQLCOM_FLUSH= 2048,
/**
Marks routines that directly (i.e. not by calling other routines)
change tables. Note that this flag is set automatically based on
type of statements used in the stored routine and is different
from routine characteristic provided by user in a form of CONTAINS
SQL, READS SQL DATA, MODIFIES SQL DATA clauses. The latter are
accepted by parser but pretty much ignored after that.
We don't rely on them:
a) for compatibility reasons.
b) because in CONTAINS SQL case they don't provide enough
information anyway.
*/
MODIFIES_DATA= 4096,
/*
Marks routines that have column type references: DECLARE a t1.a%TYPE;
*/
HAS_COLUMN_TYPE_REFS= 8192,
/* Set if has FETCH GROUP NEXT ROW instr. Used to ensure that only
functions with AGGREGATE keyword use the instr. */
HAS_AGGREGATE_INSTR= 16384
};
sp_package *m_parent;
const Sp_handler *m_handler;
uint m_flags; // Boolean attributes of a stored routine
Column_definition m_return_field_def; /**< This is used for FUNCTIONs only. */
const char *m_tmp_query; ///< Temporary pointer to sub query string
private:
/*
Private to guarantee that m_chistics.comment is properly set to:
- a string which is alloced on this->mem_root
- or (NULL,0)
set_chistics() makes sure this.
*/
Sp_chistics m_chistics;
void set_chistics(const st_sp_chistics &chistics);
inline void set_chistics_agg_type(enum enum_sp_aggregate_type type)
{
m_chistics.agg_type= type;
}
public:
sql_mode_t m_sql_mode; ///< For SHOW CREATE and execution
bool m_explicit_name; /**< Prepend the db name? */
LEX_CSTRING m_qname; ///< db.name
LEX_CSTRING m_params;
LEX_CSTRING m_body;
LEX_CSTRING m_body_utf8;
LEX_CSTRING m_defstr;
AUTHID m_definer;
const st_sp_chistics &chistics() const { return m_chistics; }
const LEX_CSTRING &comment() const { return m_chistics.comment; }
void set_suid(enum_sp_suid_behaviour suid) { m_chistics.suid= suid; }
enum_sp_suid_behaviour suid() const { return m_chistics.suid; }
bool detistic() const { return m_chistics.detistic; }
enum_sp_data_access daccess() const { return m_chistics.daccess; }
enum_sp_aggregate_type agg_type() const { return m_chistics.agg_type; }
/**
Is this routine being executed?
*/
virtual bool is_invoked() const { return m_flags & IS_INVOKED; }
/**
Get the value of the SP cache version, as remembered
when the routine was inserted into the cache.
*/
ulong sp_cache_version() const;
/** Set the value of the SP cache version. */
void set_sp_cache_version(ulong version_arg) const
{
m_sp_cache_version= version_arg;
}
sp_rcontext *rcontext_create(THD *thd, Field *retval, List<Item> *args);
sp_rcontext *rcontext_create(THD *thd, Field *retval,
Item **args, uint arg_count);
sp_rcontext *rcontext_create(THD *thd, Field *retval,
Row_definition_list *list,
bool switch_security_ctx);
bool eq_routine_spec(const sp_head *) const;
private:
/**
Version of the stored routine cache at the moment when the
routine was added to it. Is used only for functions and
procedures, not used for triggers or events. When sp_head is
created, its version is 0. When it's added to the cache, the
version is assigned the global value 'Cversion'.
If later on Cversion is incremented, we know that the routine
is obsolete and should not be used --
sp_cache_flush_obsolete() will purge it.
*/
mutable ulong m_sp_cache_version;
Stored_program_creation_ctx *m_creation_ctx;
/**
Boolean combination of (1<<flag), where flag is a member of
LEX::enum_binlog_stmt_unsafe.
*/
uint32 unsafe_flags;
public:
inline Stored_program_creation_ctx *get_creation_ctx()
{
return m_creation_ctx;
}
inline void set_creation_ctx(Stored_program_creation_ctx *creation_ctx)
{
m_creation_ctx= creation_ctx->clone(mem_root);
}
longlong m_created;
longlong m_modified;
/** Recursion level of the current SP instance. The levels are numbered from 0 */
ulong m_recursion_level;
/**
A list of diferent recursion level instances for the same procedure.
For every recursion level we have a sp_head instance. This instances
connected in the list. The list ordered by increasing recursion level
(m_recursion_level).
*/
sp_head *m_next_cached_sp;
/**
Pointer to the first element of the above list
*/
sp_head *m_first_instance;
/**
Pointer to the first free (non-INVOKED) routine in the list of
cached instances for this SP. This pointer is set only for the first
SP in the list of instences (see above m_first_cached_sp pointer).
The pointer equal to 0 if we have no free instances.
For non-first instance value of this pointer meanless (point to itself);
*/
sp_head *m_first_free_instance;
/**
Pointer to the last element in the list of instances of the SP.
For non-first instance value of this pointer meanless (point to itself);
*/
sp_head *m_last_cached_sp;
/**
Set containing names of stored routines used by this routine.
Note that unlike elements of similar set for statement elements of this
set are not linked in one list. Because of this we are able save memory
by using for this set same objects that are used in 'sroutines' sets
for statements of which this stored routine consists.
*/
HASH m_sroutines;
// Pointers set during parsing
const char *m_param_begin;
const char *m_param_end;
private:
const char *m_body_begin;
public:
/*
Security context for stored routine which should be run under
definer privileges.
*/
Security_context m_security_ctx;
/**
List of all items (Item_trigger_field objects) representing fields in
old/new version of row in trigger. We use this list for checking whenever
all such fields are valid at trigger creation time and for binding these
fields to TABLE object at table open (although for latter pointer to table
being opened is probably enough).
*/
SQL_I_List<Item_trigger_field> m_trg_table_fields;
protected:
sp_head(MEM_ROOT *mem_root, sp_package *parent, const Sp_handler *handler,
enum_sp_aggregate_type agg_type);
virtual ~sp_head();
public:
static void destroy(sp_head *sp);
static sp_head *create(sp_package *parent, const Sp_handler *handler,
enum_sp_aggregate_type agg_type);
/// Initialize after we have reset mem_root
void
init(LEX *lex);
/** Copy sp name from parser. */
void
init_sp_name(const sp_name *spname);
/** Set the body-definition start position. */
void
set_body_start(THD *thd, const char *begin_ptr);
/** Set the statement-definition (body-definition) end position. */
void
set_stmt_end(THD *thd);
bool
execute_trigger(THD *thd,
const LEX_CSTRING *db_name,
const LEX_CSTRING *table_name,
GRANT_INFO *grant_info);
bool
execute_function(THD *thd, Item **args, uint argcount, Field *return_fld,
sp_rcontext **nctx, Query_arena *call_arena);
bool
execute_procedure(THD *thd, List<Item> *args);
static void
show_create_routine_get_fields(THD *thd, const Sp_handler *sph,
List<Item> *fields);
bool
show_create_routine(THD *thd, const Sp_handler *sph);
MEM_ROOT *get_main_mem_root() { return &main_mem_root; }
int
add_instr(sp_instr *instr);
bool
add_instr_jump(THD *thd, sp_pcontext *spcont);
bool
add_instr_jump(THD *thd, sp_pcontext *spcont, uint dest);
bool
add_instr_jump_forward_with_backpatch(THD *thd, sp_pcontext *spcont,
sp_label *lab);
bool
add_instr_jump_forward_with_backpatch(THD *thd, sp_pcontext *spcont)
{
return add_instr_jump_forward_with_backpatch(thd, spcont,
spcont->last_label());
}
bool
add_instr_freturn(THD *thd, sp_pcontext *spcont, Item *item, LEX *lex);
bool
add_instr_preturn(THD *thd, sp_pcontext *spcont);
Item *adjust_assignment_source(THD *thd, Item *val, Item *val2);
/**
@param thd - the current thd
@param spcont - the current parse context
@param spv - the SP variable
@param val - the value to be assigned to the variable
@param lex - the LEX that was used to create "val"
@param responsible_to_free_lex - if the generated sp_instr_set should
free "lex".
@retval true - on error
@retval false - on success
*/
bool set_local_variable(THD *thd, sp_pcontext *spcont,
const Sp_rcontext_handler *rh,
sp_variable *spv, Item *val, LEX *lex,
bool responsible_to_free_lex);
bool set_local_variable_row_field(THD *thd, sp_pcontext *spcont,
const Sp_rcontext_handler *rh,
sp_variable *spv, uint field_idx,
Item *val, LEX *lex);
bool set_local_variable_row_field_by_name(THD *thd, sp_pcontext *spcont,
const Sp_rcontext_handler *rh,
sp_variable *spv,
const LEX_CSTRING *field_name,
Item *val, LEX *lex);
bool check_package_routine_end_name(const LEX_CSTRING &end_name) const;
bool check_standalone_routine_end_name(const sp_name *end_name) const;
bool check_group_aggregate_instructions_function() const;
bool check_group_aggregate_instructions_forbid() const;
bool check_group_aggregate_instructions_require() const;
private:
/**
Generate a code to set a single cursor parameter variable.
@param thd - current thd, for mem_root allocations.
@param param_spcont - the context of the parameter block
@param idx - the index of the parameter
@param prm - the actual parameter (contains information about
the assignment source expression Item,
its free list, and its LEX)
*/
bool add_set_cursor_param_variable(THD *thd,
sp_pcontext *param_spcont, uint idx,
sp_assignment_lex *prm)
{
DBUG_ASSERT(idx < param_spcont->context_var_count());
sp_variable *spvar= param_spcont->get_context_variable(idx);
/*
add_instr() gets free_list from m_thd->free_list.
Initialize it before the set_local_variable() call.
*/
DBUG_ASSERT(m_thd->free_list == NULL);
m_thd->free_list= prm->get_free_list();
if (set_local_variable(thd, param_spcont,
&sp_rcontext_handler_local,
spvar, prm->get_item(), prm, true))
return true;
/*
Safety:
The item and its free_list are now fully owned by the sp_instr_set
instance, created by set_local_variable(). The sp_instr_set instance
is now responsible for freeing the item and the free_list.
Reset the "item" and the "free_list" members of "prm",
to avoid double pointers to the same objects from "prm" and
from the sp_instr_set instance.
*/
prm->set_item_and_free_list(NULL, NULL);
return false;
}
/**
Generate a code to set all cursor parameter variables.
This method is called only when parameters exists,
and the number of formal parameters matches the number of actual
parameters. See also comments to add_open_cursor().
*/
bool add_set_cursor_param_variables(THD *thd, sp_pcontext *param_spcont,
List<sp_assignment_lex> *parameters)
{
DBUG_ASSERT(param_spcont->context_var_count() == parameters->elements);
sp_assignment_lex *prm;
List_iterator<sp_assignment_lex> li(*parameters);
for (uint idx= 0; (prm= li++); idx++)
{
if (add_set_cursor_param_variable(thd, param_spcont, idx, prm))
return true;
}
return false;
}
/**
Generate a code to set all cursor parameter variables for a FOR LOOP, e.g.:
FOR index IN cursor(1,2,3)
@param
*/
bool add_set_for_loop_cursor_param_variables(THD *thd,
sp_pcontext *param_spcont,
sp_assignment_lex *param_lex,
Item_args *parameters);
public:
/**
Generate a code for an "OPEN cursor" statement.
@param thd - current thd, for mem_root allocations
@param spcont - the context of the cursor
@param offset - the offset of the cursor
@param param_spcont - the context of the cursor parameter block
@param parameters - the list of the OPEN actual parameters
The caller must make sure that the number of local variables
in "param_spcont" (formal parameters) matches the number of list elements
in "parameters" (actual parameters).
NULL in either of them means 0 parameters.
*/
bool add_open_cursor(THD *thd, sp_pcontext *spcont,
uint offset,
sp_pcontext *param_spcont,
List<sp_assignment_lex> *parameters);
/**
Generate an initiation code for a CURSOR FOR LOOP, e.g.:
FOR index IN cursor -- cursor without parameters
FOR index IN cursor(1,2,3) -- cursor with parameters
The code generated by this method does the following during SP run-time:
- Sets all cursor parameter vartiables from "parameters"
- Initializes the index ROW-type variable from the cursor
(the structure is copied from the cursor to the index variable)
- The cursor gets opened
- The first records is fetched from the cursor to the variable "index".
@param thd - the current thread (for mem_root and error reporting)
@param spcont - the current parse context
@param index - the loop "index" ROW-type variable
@param pcursor - the cursor
@param coffset - the cursor offset
@param param_lex - the LEX that owns Items in "parameters"
@param parameters - the cursor parameters Item array
@retval true - on error (EOM)
@retval false - on success
*/
bool add_for_loop_open_cursor(THD *thd, sp_pcontext *spcont,
sp_variable *index,
const sp_pcursor *pcursor, uint coffset,
sp_assignment_lex *param_lex,
Item_args *parameters);
/**
Returns true if any substatement in the routine directly
(not through another routine) modifies data/changes table.
@sa Comment for MODIFIES_DATA flag.
*/
bool modifies_data() const
{ return m_flags & MODIFIES_DATA; }
inline uint instructions()
{ return m_instr.elements; }
inline sp_instr *
last_instruction()
{
sp_instr *i;
get_dynamic(&m_instr, (uchar*)&i, m_instr.elements-1);
return i;
}
bool replace_instr_to_nop(THD *thd, uint ip);
/*
Resets lex in 'thd' and keeps a copy of the old one.
@todo Conflicting comment in sp_head.cc
*/
bool
reset_lex(THD *thd);
bool
reset_lex(THD *thd, sp_lex_local *sublex);
/**
Merge two LEX instances.
@param oldlex - the upper level LEX we're going to restore to.
@param sublex - the local lex that have just parsed some substatement.
@returns - false on success, true on error (e.g. failed to
merge the routine list or the table list).
This method is shared by:
- restore_lex(), when the old LEX is popped by sp_head::m_lex.pop()
- THD::restore_from_local_lex_to_old_lex(), when the old LEX
is stored in the caller's local variable.
*/
bool
merge_lex(THD *thd, LEX *oldlex, LEX *sublex);
/**
Restores lex in 'thd' from our copy, but keeps some status from the
one in 'thd', like ptr, tables, fields, etc.
@todo Conflicting comment in sp_head.cc
*/
bool
restore_lex(THD *thd)
{
DBUG_ENTER("sp_head::restore_lex");
LEX *oldlex= (LEX *) m_lex.pop();
if (!oldlex)
DBUG_RETURN(false); // Nothing to restore
LEX *sublex= thd->lex;
// This restores thd->lex and thd->stmt_lex
if (thd->restore_from_local_lex_to_old_lex(oldlex))
DBUG_RETURN(true);
if (!sublex->sp_lex_in_use)
{
sublex->sphead= NULL;
lex_end(sublex);
delete sublex;
}
DBUG_RETURN(false);
}
/// Put the instruction on the backpatch list, associated with the label.
int
push_backpatch(THD *thd, sp_instr *, sp_label *);
int
push_backpatch_goto(THD *thd, sp_pcontext *ctx, sp_label *lab);
/// Update all instruction with this label in the backpatch list to
/// the current position.
void
backpatch(sp_label *);
void
backpatch_goto(THD *thd, sp_label *, sp_label *);
/// Check for unresolved goto label
bool
check_unresolved_goto();
/// Start a new cont. backpatch level. If 'i' is NULL, the level is just incr.
int
new_cont_backpatch(sp_instr_opt_meta *i);
/// Add an instruction to the current level
int
add_cont_backpatch(sp_instr_opt_meta *i);
/// Backpatch (and pop) the current level to the current position.
void
do_cont_backpatch();
/// Add cpush instructions for all cursors declared in the current frame
bool sp_add_instr_cpush_for_cursors(THD *thd, sp_pcontext *pcontext);
const LEX_CSTRING *name() const
{ return &m_name; }
char *create_string(THD *thd, ulong *lenp);
Field *create_result_field(uint field_max_length, const LEX_CSTRING *field_name,
TABLE *table) const;
/**
Check and prepare an instance of Column_definition for field creation
(fill all necessary attributes), for variables, parameters and
function return values.
@param[in] thd Thread handle
@param[in] lex Yacc parsing context
@param[out] field_def An instance of create_field to be filled
@retval false on success
@retval true on error
*/
bool fill_field_definition(THD *thd, Column_definition *field_def)
{
const Type_handler *h= field_def->type_handler();
return h->Column_definition_fix_attributes(field_def) ||
field_def->sp_prepare_create_field(thd, mem_root);
}
bool row_fill_field_definitions(THD *thd, Row_definition_list *row)
{
/*
Prepare all row fields. This will (among other things)
- convert VARCHAR lengths from character length to octet length
- calculate interval lengths for SET and ENUM
*/
List_iterator<Spvar_definition> it(*row);
for (Spvar_definition *def= it++; def; def= it++)
{
if (fill_spvar_definition(thd, def))
return true;
}
return false;
}
/**
Check and prepare a Column_definition for a variable or a parameter.
*/
bool fill_spvar_definition(THD *thd, Column_definition *def)
{
if (fill_field_definition(thd, def))
return true;
def->pack_flag|= FIELDFLAG_MAYBE_NULL;
return false;
}
bool fill_spvar_definition(THD *thd, Column_definition *def,
LEX_CSTRING *name)
{
def->field_name= *name;
return fill_spvar_definition(thd, def);
}
private:
/**
Set a column type reference for a parameter definition
*/
void fill_spvar_using_type_reference(sp_variable *spvar,
Qualified_column_ident *ref)
{
spvar->field_def.set_column_type_ref(ref);
spvar->field_def.field_name= spvar->name;
m_flags|= sp_head::HAS_COLUMN_TYPE_REFS;
}
void fill_spvar_using_table_rowtype_reference(THD *thd,
sp_variable *spvar,
Table_ident *ref)
{
spvar->field_def.set_table_rowtype_ref(ref);
spvar->field_def.field_name= spvar->name;
fill_spvar_definition(thd, &spvar->field_def);
m_flags|= sp_head::HAS_COLUMN_TYPE_REFS;
}
public:
bool spvar_fill_row(THD *thd, sp_variable *spvar, Row_definition_list *def);
bool spvar_fill_type_reference(THD *thd, sp_variable *spvar,
const LEX_CSTRING &table,
const LEX_CSTRING &column);
bool spvar_fill_type_reference(THD *thd, sp_variable *spvar,
const LEX_CSTRING &db,
const LEX_CSTRING &table,
const LEX_CSTRING &column);
bool spvar_fill_table_rowtype_reference(THD *thd, sp_variable *spvar,
const LEX_CSTRING &table);
bool spvar_fill_table_rowtype_reference(THD *thd, sp_variable *spvar,
const LEX_CSTRING &db,
const LEX_CSTRING &table);
void set_c_chistics(const st_sp_chistics &chistics);
void set_info(longlong created, longlong modified,
const st_sp_chistics &chistics, sql_mode_t sql_mode);
void set_definer(const char *definer, size_t definerlen)
{
AUTHID tmp;
tmp.parse(definer, definerlen);
m_definer.copy(mem_root, &tmp.user, &tmp.host);
}
void set_definer(const LEX_CSTRING *user_name, const LEX_CSTRING *host_name)
{
m_definer.copy(mem_root, user_name, host_name);
}
void reset_thd_mem_root(THD *thd);
void restore_thd_mem_root(THD *thd);
/**
Optimize the code.
*/
void optimize();
/**
Helper used during flow analysis during code optimization.
See the implementation of <code>opt_mark()</code>.
@param ip the instruction to add to the leads list
@param leads the list of remaining paths to explore in the graph that
represents the code, during flow analysis.
*/
void add_mark_lead(uint ip, List<sp_instr> *leads);
inline sp_instr *
get_instr(uint i)
{
sp_instr *ip;
if (i < m_instr.elements)
get_dynamic(&m_instr, (uchar*)&ip, i);
else
ip= NULL;
return ip;
}
/* Add tables used by routine to the table list. */
bool add_used_tables_to_table_list(THD *thd,
TABLE_LIST ***query_tables_last_ptr,
TABLE_LIST *belong_to_view);
/**
Check if this stored routine contains statements disallowed
in a stored function or trigger, and set an appropriate error message
if this is the case.
*/
bool is_not_allowed_in_function(const char *where)
{
if (m_flags & CONTAINS_DYNAMIC_SQL)
my_error(ER_STMT_NOT_ALLOWED_IN_SF_OR_TRG, MYF(0), "Dynamic SQL");
else if (m_flags & MULTI_RESULTS)
my_error(ER_SP_NO_RETSET, MYF(0), where);
else if (m_flags & HAS_SET_AUTOCOMMIT_STMT)
my_error(ER_SP_CANT_SET_AUTOCOMMIT, MYF(0));
else if (m_flags & HAS_COMMIT_OR_ROLLBACK)
my_error(ER_COMMIT_NOT_ALLOWED_IN_SF_OR_TRG, MYF(0));
else if (m_flags & HAS_SQLCOM_RESET)
my_error(ER_STMT_NOT_ALLOWED_IN_SF_OR_TRG, MYF(0), "RESET");
else if (m_flags & HAS_SQLCOM_FLUSH)
my_error(ER_STMT_NOT_ALLOWED_IN_SF_OR_TRG, MYF(0), "FLUSH");
return MY_TEST(m_flags &
(CONTAINS_DYNAMIC_SQL | MULTI_RESULTS |
HAS_SET_AUTOCOMMIT_STMT | HAS_COMMIT_OR_ROLLBACK |
HAS_SQLCOM_RESET | HAS_SQLCOM_FLUSH));
}
#ifndef DBUG_OFF
int show_routine_code(THD *thd);
#endif
/*
This method is intended for attributes of a routine which need
to propagate upwards to the Query_tables_list of the caller (when
a property of a sp_head needs to "taint" the calling statement).
*/
void propagate_attributes(Query_tables_list *prelocking_ctx)
{
DBUG_ENTER("sp_head::propagate_attributes");
/*
If this routine needs row-based binary logging, the entire top statement
too (we cannot switch from statement-based to row-based only for this
routine, as in statement-based the top-statement may be binlogged and
the substatements not).
*/
DBUG_PRINT("info", ("lex->get_stmt_unsafe_flags(): 0x%x",
prelocking_ctx->get_stmt_unsafe_flags()));
DBUG_PRINT("info", ("sp_head(%p=%s)->unsafe_flags: 0x%x",
this, name()->str, unsafe_flags));
prelocking_ctx->set_stmt_unsafe_flags(unsafe_flags);
DBUG_VOID_RETURN;
}
sp_pcontext *get_parse_context() { return m_pcont; }
/*
Check EXECUTE access:
- in case of a standalone rotuine, for the routine itself
- in case of a package routine, for the owner package body
*/
bool check_execute_access(THD *thd) const;
virtual sp_package *get_package()
{
return NULL;
}
protected:
MEM_ROOT *m_thd_root; ///< Temp. store for thd's mem_root
THD *m_thd; ///< Set if we have reset mem_root
sp_pcontext *m_pcont; ///< Parse context
List<LEX> m_lex; ///< Temp. store for the other lex
DYNAMIC_ARRAY m_instr; ///< The "instructions"
enum backpatch_instr_type { GOTO, CPOP, HPOP };
typedef struct
{
sp_label *lab;
sp_instr *instr;
backpatch_instr_type instr_type;
} bp_t;
List<bp_t> m_backpatch; ///< Instructions needing backpatching
List<bp_t> m_backpatch_goto; // Instructions needing backpatching (for goto)
/**
We need a special list for backpatching of instructions with a continue
destination (in the case of a continue handler catching an error in
the test), since it would otherwise interfere with the normal backpatch
mechanism - e.g. jump_if_not instructions have two different destinations
which are to be patched differently.
Since these occur in a more restricted way (always the same "level" in
the code), we don't need the label.
*/
List<sp_instr_opt_meta> m_cont_backpatch;
uint m_cont_level; // The current cont. backpatch level
/**
Multi-set representing optimized list of tables to be locked by this
routine. Does not include tables which are used by invoked routines.
@note
For prelocking-free SPs this multiset is constructed too.
We do so because the same instance of sp_head may be called both
in prelocked mode and in non-prelocked mode.
*/
HASH m_sptabs;
bool
execute(THD *thd, bool merge_da_on_success);
/**
Perform a forward flow analysis in the generated code.
Mark reachable instructions, for the optimizer.
*/
void opt_mark();
/**
Merge the list of tables used by query into the multi-set of tables used
by routine.
*/
bool merge_table_list(THD *thd, TABLE_LIST *table, LEX *lex_for_tmp_check);
/// Put the instruction on the a backpatch list, associated with the label.
int
push_backpatch(THD *thd, sp_instr *, sp_label *, List<bp_t> *list,
backpatch_instr_type itype);
}; // class sp_head : public Sql_alloc
class sp_package: public sp_head
{
bool validate_public_routines(THD *thd, sp_package *spec);
bool validate_private_routines(THD *thd);
public:
class LexList: public List<LEX>
{
public:
LexList() { elements= 0; }
// Find a package routine by a non qualified name
LEX *find(const LEX_CSTRING &name, stored_procedure_type type);
// Find a package routine by a package-qualified name, e.g. 'pkg.proc'
LEX *find_qualified(const LEX_CSTRING &name, stored_procedure_type type);
// Check if a routine with the given qualified name already exists
bool check_dup_qualified(const LEX_CSTRING &name, const Sp_handler *sph)
{
if (!find_qualified(name, sph->type()))
return false;
my_error(ER_SP_ALREADY_EXISTS, MYF(0), sph->type_str(), name.str);
return true;
}
bool check_dup_qualified(const sp_head *sp)
{
return check_dup_qualified(sp->m_name, sp->m_handler);
}
void cleanup();
};
/*
The LEX for a new package subroutine is initially assigned to
m_current_routine. After scanning parameters, return type and chistics,
the parser detects if we have a declaration or a definition, e.g.:
PROCEDURE p1(a INT);
vs
PROCEDURE p1(a INT) AS BEGIN NULL; END;
(i.e. either semicolon or the "AS" keyword)
m_current_routine is then added either to m_routine_implementations,
or m_routine_declarations, and then m_current_routine is set to NULL.
*/
LEX *m_current_routine;
LexList m_routine_implementations;
LexList m_routine_declarations;
LEX *m_top_level_lex;
sp_rcontext *m_rcontext;
uint m_invoked_subroutine_count;
bool m_is_instantiated;
bool m_is_cloning_routine;
private:
sp_package(MEM_ROOT *mem_root,
LEX *top_level_lex,
const sp_name *name,
const Sp_handler *sph);
~sp_package();
public:
static sp_package *create(LEX *top_level_lex, const sp_name *name,
const Sp_handler *sph);
bool add_routine_declaration(LEX *lex)
{
return m_routine_declarations.check_dup_qualified(lex->sphead) ||
m_routine_declarations.push_back(lex, &main_mem_root);
}
bool add_routine_implementation(LEX *lex)
{
return m_routine_implementations.check_dup_qualified(lex->sphead) ||
m_routine_implementations.push_back(lex, &main_mem_root);
}
sp_package *get_package() { return this; }
bool is_invoked() const
{
/*
Cannot flush a package out of the SP cache when:
- its initialization block is running
- one of its subroutine is running
*/
return sp_head::is_invoked() || m_invoked_subroutine_count > 0;
}
sp_variable *find_package_variable(const LEX_CSTRING *name) const
{
/*
sp_head::m_pcont is a special level for routine parameters.
Variables declared inside CREATE PACKAGE BODY reside in m_children.at(0).
*/
sp_pcontext *ctx= m_pcont->child_context(0);
return ctx ? ctx->find_variable(name, true) : NULL;
}
bool validate_after_parser(THD *thd);
bool instantiate_if_needed(THD *thd);
};
class sp_lex_cursor: public sp_lex_local, public Query_arena
{
public:
sp_lex_cursor(THD *thd, const LEX *oldlex, MEM_ROOT *mem_root_arg)
:sp_lex_local(thd, oldlex),
Query_arena(mem_root_arg, STMT_INITIALIZED_FOR_SP)
{ }
sp_lex_cursor(THD *thd, const LEX *oldlex)
:sp_lex_local(thd, oldlex),
Query_arena(thd->lex->sphead->get_main_mem_root(), STMT_INITIALIZED_FOR_SP)
{ }
~sp_lex_cursor() { free_items(); }
void cleanup_stmt() { }
Query_arena *query_arena() { return this; }
bool validate()
{
DBUG_ASSERT(sql_command == SQLCOM_SELECT);
if (result)
{
my_error(ER_SP_BAD_CURSOR_SELECT, MYF(0));
return true;
}
return false;
}
bool stmt_finalize(THD *thd)
{
if (validate())
return true;
sp_lex_in_use= true;
free_list= thd->free_list;
thd->free_list= NULL;
return false;
}
};
//
// "Instructions"...
//
class sp_instr :public Query_arena, public Sql_alloc
{
sp_instr(const sp_instr &); /**< Prevent use of these */
void operator=(sp_instr &);
public:
uint marked;
uint m_ip; ///< My index
sp_pcontext *m_ctx; ///< My parse context
uint m_lineno;
/// Should give each a name or type code for debugging purposes?
sp_instr(uint ip, sp_pcontext *ctx)
:Query_arena(0, STMT_INITIALIZED_FOR_SP), marked(0), m_ip(ip), m_ctx(ctx)
{}
virtual ~sp_instr()
{ free_items(); }
/**
Execute this instruction
@param thd Thread handle
@param[out] nextp index of the next instruction to execute. (For most
instructions this will be the instruction following this
one). Note that this parameter is undefined in case of
errors, use get_cont_dest() to find the continuation
instruction for CONTINUE error handlers.
@retval 0 on success,
@retval other if some error occurred
*/
virtual int execute(THD *thd, uint *nextp) = 0;
/**
Execute <code>open_and_lock_tables()</code> for this statement.
Open and lock the tables used by this statement, as a pre-requisite
to execute the core logic of this instruction with
<code>exec_core()</code>.
@param thd the current thread
@param tables the list of tables to open and lock
@return zero on success, non zero on failure.
*/
int exec_open_and_lock_tables(THD *thd, TABLE_LIST *tables);
/**
Get the continuation destination of this instruction.
@return the continuation destination
*/
virtual uint get_cont_dest() const;
/*
Execute core function of instruction after all preparations (e.g.
setting of proper LEX, saving part of the thread context have been
done).
Should be implemented for instructions using expressions or whole
statements (thus having to have own LEX). Used in concert with
sp_lex_keeper class and its descendants (there are none currently).
*/
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str) = 0;
virtual void backpatch(uint dest, sp_pcontext *dst_ctx)
{}
/**
Mark this instruction as reachable during optimization and return the
index to the next instruction. Jump instruction will add their
destination to the leads list.
*/
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads)
{
marked= 1;
return m_ip+1;
}
/**
Short-cut jumps to jumps during optimization. This is used by the
jump instructions' opt_mark() methods. 'start' is the starting point,
used to prevent the mark sweep from looping for ever. Return the
end destination.
*/
virtual uint opt_shortcut_jump(sp_head *sp, sp_instr *start)
{
return m_ip;
}
/**
Inform the instruction that it has been moved during optimization.
Most instructions will simply update its index, but jump instructions
must also take care of their destination pointers. Forward jumps get
pushed to the backpatch list 'ibp'.
*/
virtual void opt_move(uint dst, List<sp_instr> *ibp)
{
m_ip= dst;
}
}; // class sp_instr : public Sql_alloc
/**
Auxilary class to which instructions delegate responsibility
for handling LEX and preparations before executing statement
or calculating complex expression.
Exist mainly to avoid having double hierarchy between instruction
classes.
@todo
Add ability to not store LEX and do any preparations if
expression used is simple.
*/
class sp_lex_keeper
{
/** Prevent use of these */
sp_lex_keeper(const sp_lex_keeper &);
void operator=(sp_lex_keeper &);
public:
sp_lex_keeper(LEX *lex, bool lex_resp)
: m_lex(lex), m_lex_resp(lex_resp),
lex_query_tables_own_last(NULL)
{
lex->sp_lex_in_use= TRUE;
}
virtual ~sp_lex_keeper()
{
if (m_lex_resp)
{
/* Prevent endless recursion. */
m_lex->sphead= NULL;
lex_end(m_lex);
delete m_lex;
}
}
/**
Prepare execution of instruction using LEX, if requested check whenever
we have read access to tables used and open/lock them, call instruction's
exec_core() method, perform cleanup afterwards.
@todo Conflicting comment in sp_head.cc
*/
int reset_lex_and_exec_core(THD *thd, uint *nextp, bool open_tables,
sp_instr* instr);
int cursor_reset_lex_and_exec_core(THD *thd, uint *nextp, bool open_tables,
sp_instr *instr);
inline uint sql_command() const
{
return (uint)m_lex->sql_command;
}
void disable_query_cache()
{
m_lex->safe_to_cache_query= 0;
}
private:
LEX *m_lex;
/**
Indicates whenever this sp_lex_keeper instance responsible
for LEX deletion.
*/
bool m_lex_resp;
/*
Support for being able to execute this statement in two modes:
a) inside prelocked mode set by the calling procedure or its ancestor.
b) outside of prelocked mode, when this statement enters/leaves
prelocked mode itself.
*/
/**
List of additional tables this statement needs to lock when it
enters/leaves prelocked mode on its own.
*/
TABLE_LIST *prelocking_tables;
/**
The value m_lex->query_tables_own_last should be set to this when the
statement enters/leaves prelocked mode on its own.
*/
TABLE_LIST **lex_query_tables_own_last;
};
/**
Call out to some prepared SQL statement.
*/
class sp_instr_stmt : public sp_instr
{
sp_instr_stmt(const sp_instr_stmt &); /**< Prevent use of these */
void operator=(sp_instr_stmt &);
public:
LEX_STRING m_query; ///< For thd->query
sp_instr_stmt(uint ip, sp_pcontext *ctx, LEX *lex)
: sp_instr(ip, ctx), m_lex_keeper(lex, TRUE)
{
m_query.str= 0;
m_query.length= 0;
}
virtual ~sp_instr_stmt()
{};
virtual int execute(THD *thd, uint *nextp);
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
private:
sp_lex_keeper m_lex_keeper;
}; // class sp_instr_stmt : public sp_instr
class sp_instr_set : public sp_instr
{
sp_instr_set(const sp_instr_set &); /**< Prevent use of these */
void operator=(sp_instr_set &);
public:
sp_instr_set(uint ip, sp_pcontext *ctx,
const Sp_rcontext_handler *rh,
uint offset, Item *val,
LEX *lex, bool lex_resp)
: sp_instr(ip, ctx),
m_rcontext_handler(rh), m_offset(offset), m_value(val),
m_lex_keeper(lex, lex_resp)
{}
virtual ~sp_instr_set()
{}
virtual int execute(THD *thd, uint *nextp);
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
protected:
sp_rcontext *get_rcontext(THD *thd) const;
const Sp_rcontext_handler *m_rcontext_handler;
uint m_offset; ///< Frame offset
Item *m_value;
sp_lex_keeper m_lex_keeper;
}; // class sp_instr_set : public sp_instr
/*
This class handles assignments of a ROW fields:
DECLARE rec ROW (a INT,b INT);
SET rec.a= 10;
*/
class sp_instr_set_row_field : public sp_instr_set
{
sp_instr_set_row_field(const sp_instr_set_row_field &); // Prevent use of this
void operator=(sp_instr_set_row_field &);
uint m_field_offset;
public:
sp_instr_set_row_field(uint ip, sp_pcontext *ctx,
const Sp_rcontext_handler *rh,
uint offset, uint field_offset,
Item *val,
LEX *lex, bool lex_resp)
: sp_instr_set(ip, ctx, rh, offset, val, lex, lex_resp),
m_field_offset(field_offset)
{}
virtual ~sp_instr_set_row_field()
{}
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
}; // class sp_instr_set_field : public sp_instr_set
/**
This class handles assignment instructions like this:
DECLARE
CURSOR cur IS SELECT * FROM t1;
rec cur%ROWTYPE;
BEGIN
rec.column1:= 10; -- This instruction
END;
The idea is that during sp_rcontext::create() we do not know the extact
structure of "rec". It gets resolved at run time, during the corresponding
sp_instr_cursor_copy_struct::exec_core().
So sp_instr_set_row_field_by_name searches for ROW fields by name,
while sp_instr_set_row_field (see above) searches for ROW fields by index.
*/
class sp_instr_set_row_field_by_name : public sp_instr_set
{
// Prevent use of this
sp_instr_set_row_field_by_name(const sp_instr_set_row_field &);
void operator=(sp_instr_set_row_field_by_name &);
const LEX_CSTRING m_field_name;
public:
sp_instr_set_row_field_by_name(uint ip, sp_pcontext *ctx,
const Sp_rcontext_handler *rh,
uint offset, const LEX_CSTRING &field_name,
Item *val,
LEX *lex, bool lex_resp)
: sp_instr_set(ip, ctx, rh, offset, val, lex, lex_resp),
m_field_name(field_name)
{}
virtual ~sp_instr_set_row_field_by_name()
{}
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
}; // class sp_instr_set_field_by_name : public sp_instr_set
/**
Set NEW/OLD row field value instruction. Used in triggers.
*/
class sp_instr_set_trigger_field : public sp_instr
{
sp_instr_set_trigger_field(const sp_instr_set_trigger_field &);
void operator=(sp_instr_set_trigger_field &);
public:
sp_instr_set_trigger_field(uint ip, sp_pcontext *ctx,
Item_trigger_field *trg_fld,
Item *val, LEX *lex)
: sp_instr(ip, ctx),
trigger_field(trg_fld),
value(val), m_lex_keeper(lex, TRUE)
{}
virtual ~sp_instr_set_trigger_field()
{}
virtual int execute(THD *thd, uint *nextp);
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
private:
Item_trigger_field *trigger_field;
Item *value;
sp_lex_keeper m_lex_keeper;
}; // class sp_instr_trigger_field : public sp_instr
/**
An abstract class for all instructions with destinations that
needs to be updated by the optimizer.
Even if not all subclasses will use both the normal destination and
the continuation destination, we put them both here for simplicity.
*/
class sp_instr_opt_meta : public sp_instr
{
public:
uint m_dest; ///< Where we will go
uint m_cont_dest; ///< Where continue handlers will go
sp_instr_opt_meta(uint ip, sp_pcontext *ctx)
: sp_instr(ip, ctx),
m_dest(0), m_cont_dest(0), m_optdest(0), m_cont_optdest(0)
{}
sp_instr_opt_meta(uint ip, sp_pcontext *ctx, uint dest)
: sp_instr(ip, ctx),
m_dest(dest), m_cont_dest(0), m_optdest(0), m_cont_optdest(0)
{}
virtual ~sp_instr_opt_meta()
{}
virtual void set_destination(uint old_dest, uint new_dest)
= 0;
virtual uint get_cont_dest() const;
protected:
sp_instr *m_optdest; ///< Used during optimization
sp_instr *m_cont_optdest; ///< Used during optimization
}; // class sp_instr_opt_meta : public sp_instr
class sp_instr_jump : public sp_instr_opt_meta
{
sp_instr_jump(const sp_instr_jump &); /**< Prevent use of these */
void operator=(sp_instr_jump &);
public:
sp_instr_jump(uint ip, sp_pcontext *ctx)
: sp_instr_opt_meta(ip, ctx)
{}
sp_instr_jump(uint ip, sp_pcontext *ctx, uint dest)
: sp_instr_opt_meta(ip, ctx, dest)
{}
virtual ~sp_instr_jump()
{}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads);
virtual uint opt_shortcut_jump(sp_head *sp, sp_instr *start);
virtual void opt_move(uint dst, List<sp_instr> *ibp);
virtual void backpatch(uint dest, sp_pcontext *dst_ctx)
{
/* Calling backpatch twice is a logic flaw in jump resolution. */
DBUG_ASSERT(m_dest == 0);
m_dest= dest;
}
/**
Update the destination; used by the optimizer.
*/
virtual void set_destination(uint old_dest, uint new_dest)
{
if (m_dest == old_dest)
m_dest= new_dest;
}
}; // class sp_instr_jump : public sp_instr_opt_meta
class sp_instr_jump_if_not : public sp_instr_jump
{
sp_instr_jump_if_not(const sp_instr_jump_if_not &); /**< Prevent use of these */
void operator=(sp_instr_jump_if_not &);
public:
sp_instr_jump_if_not(uint ip, sp_pcontext *ctx, Item *i, LEX *lex)
: sp_instr_jump(ip, ctx), m_expr(i),
m_lex_keeper(lex, TRUE)
{}
sp_instr_jump_if_not(uint ip, sp_pcontext *ctx, Item *i, uint dest, LEX *lex)
: sp_instr_jump(ip, ctx, dest), m_expr(i),
m_lex_keeper(lex, TRUE)
{}
virtual ~sp_instr_jump_if_not()
{}
virtual int execute(THD *thd, uint *nextp);
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads);
/** Override sp_instr_jump's shortcut; we stop here */
virtual uint opt_shortcut_jump(sp_head *sp, sp_instr *start)
{
return m_ip;
}
virtual void opt_move(uint dst, List<sp_instr> *ibp);
virtual void set_destination(uint old_dest, uint new_dest)
{
sp_instr_jump::set_destination(old_dest, new_dest);
if (m_cont_dest == old_dest)
m_cont_dest= new_dest;
}
private:
Item *m_expr; ///< The condition
sp_lex_keeper m_lex_keeper;
}; // class sp_instr_jump_if_not : public sp_instr_jump
class sp_instr_preturn : public sp_instr
{
sp_instr_preturn(const sp_instr_preturn &); /**< Prevent use of these */
void operator=(sp_instr_preturn &);
public:
sp_instr_preturn(uint ip, sp_pcontext *ctx)
: sp_instr(ip, ctx)
{}
virtual ~sp_instr_preturn()
{}
virtual int execute(THD *thd, uint *nextp)
{
DBUG_ENTER("sp_instr_preturn::execute");
*nextp= UINT_MAX;
DBUG_RETURN(0);
}
virtual void print(String *str)
{
str->append(STRING_WITH_LEN("preturn"));
}
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads)
{
marked= 1;
return UINT_MAX;
}
}; // class sp_instr_preturn : public sp_instr
class sp_instr_freturn : public sp_instr
{
sp_instr_freturn(const sp_instr_freturn &); /**< Prevent use of these */
void operator=(sp_instr_freturn &);
public:
sp_instr_freturn(uint ip, sp_pcontext *ctx,
Item *val, const Type_handler *handler, LEX *lex)
: sp_instr(ip, ctx), m_value(val), m_type_handler(handler),
m_lex_keeper(lex, TRUE)
{}
virtual ~sp_instr_freturn()
{}
virtual int execute(THD *thd, uint *nextp);
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads)
{
marked= 1;
return UINT_MAX;
}
protected:
Item *m_value;
const Type_handler *m_type_handler;
sp_lex_keeper m_lex_keeper;
}; // class sp_instr_freturn : public sp_instr
class sp_instr_hpush_jump : public sp_instr_jump
{
sp_instr_hpush_jump(const sp_instr_hpush_jump &); /**< Prevent use of these */
void operator=(sp_instr_hpush_jump &);
public:
sp_instr_hpush_jump(uint ip,
sp_pcontext *ctx,
sp_handler *handler)
:sp_instr_jump(ip, ctx),
m_handler(handler),
m_opt_hpop(0),
m_frame(ctx->current_var_count())
{
DBUG_ASSERT(m_handler->condition_values.elements == 0);
}
virtual ~sp_instr_hpush_jump()
{
m_handler->condition_values.empty();
m_handler= NULL;
}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads);
/** Override sp_instr_jump's shortcut; we stop here. */
virtual uint opt_shortcut_jump(sp_head *sp, sp_instr *start)
{
return m_ip;
}
virtual void backpatch(uint dest, sp_pcontext *dst_ctx)
{
DBUG_ASSERT(!m_dest || !m_opt_hpop);
if (!m_dest)
m_dest= dest;
else
m_opt_hpop= dest;
}
void add_condition(sp_condition_value *condition_value)
{ m_handler->condition_values.push_back(condition_value); }
sp_handler *get_handler()
{ return m_handler; }
private:
/// Handler.
sp_handler *m_handler;
/// hpop marking end of handler scope.
uint m_opt_hpop;
// This attribute is needed for SHOW PROCEDURE CODE only (i.e. it's needed in
// debug version only). It's used in print().
uint m_frame;
}; // class sp_instr_hpush_jump : public sp_instr_jump
class sp_instr_hpop : public sp_instr
{
sp_instr_hpop(const sp_instr_hpop &); /**< Prevent use of these */
void operator=(sp_instr_hpop &);
public:
sp_instr_hpop(uint ip, sp_pcontext *ctx, uint count)
: sp_instr(ip, ctx), m_count(count)
{}
virtual ~sp_instr_hpop()
{}
void update_count(uint count)
{
m_count= count;
}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
private:
uint m_count;
}; // class sp_instr_hpop : public sp_instr
class sp_instr_hreturn : public sp_instr_jump
{
sp_instr_hreturn(const sp_instr_hreturn &); /**< Prevent use of these */
void operator=(sp_instr_hreturn &);
public:
sp_instr_hreturn(uint ip, sp_pcontext *ctx)
:sp_instr_jump(ip, ctx),
m_frame(ctx->current_var_count())
{}
virtual ~sp_instr_hreturn()
{}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
/* This instruction will not be short cut optimized. */
virtual uint opt_shortcut_jump(sp_head *sp, sp_instr *start)
{
return m_ip;
}
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads);
private:
uint m_frame;
}; // class sp_instr_hreturn : public sp_instr_jump
/** This is DECLARE CURSOR */
class sp_instr_cpush : public sp_instr,
public sp_cursor
{
sp_instr_cpush(const sp_instr_cpush &); /**< Prevent use of these */
void operator=(sp_instr_cpush &);
public:
sp_instr_cpush(uint ip, sp_pcontext *ctx, LEX *lex, uint offset)
: sp_instr(ip, ctx), m_lex_keeper(lex, TRUE), m_cursor(offset)
{}
virtual ~sp_instr_cpush()
{}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
/**
This call is used to cleanup the instruction when a sensitive
cursor is closed. For now stored procedures always use materialized
cursors and the call is not used.
*/
virtual void cleanup_stmt() { /* no op */ }
private:
sp_lex_keeper m_lex_keeper;
uint m_cursor; /**< Frame offset (for debugging) */
}; // class sp_instr_cpush : public sp_instr
class sp_instr_cpop : public sp_instr
{
sp_instr_cpop(const sp_instr_cpop &); /**< Prevent use of these */
void operator=(sp_instr_cpop &);
public:
sp_instr_cpop(uint ip, sp_pcontext *ctx, uint count)
: sp_instr(ip, ctx), m_count(count)
{}
virtual ~sp_instr_cpop()
{}
void update_count(uint count)
{
m_count= count;
}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
private:
uint m_count;
}; // class sp_instr_cpop : public sp_instr
class sp_instr_copen : public sp_instr
{
sp_instr_copen(const sp_instr_copen &); /**< Prevent use of these */
void operator=(sp_instr_copen &);
public:
sp_instr_copen(uint ip, sp_pcontext *ctx, uint c)
: sp_instr(ip, ctx), m_cursor(c)
{}
virtual ~sp_instr_copen()
{}
virtual int execute(THD *thd, uint *nextp);
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
private:
uint m_cursor; ///< Stack index
}; // class sp_instr_copen : public sp_instr_stmt
/**
Initialize the structure of a cursor%ROWTYPE variable
from the LEX containing the cursor SELECT statement.
*/
class sp_instr_cursor_copy_struct: public sp_instr
{
/**< Prevent use of these */
sp_instr_cursor_copy_struct(const sp_instr_cursor_copy_struct &);
void operator=(sp_instr_cursor_copy_struct &);
sp_lex_keeper m_lex_keeper;
uint m_cursor;
uint m_var;
public:
sp_instr_cursor_copy_struct(uint ip, sp_pcontext *ctx, uint coffs,
sp_lex_cursor *lex, uint voffs)
: sp_instr(ip, ctx), m_lex_keeper(lex, FALSE),
m_cursor(coffs),
m_var(voffs)
{}
virtual ~sp_instr_cursor_copy_struct()
{}
virtual int execute(THD *thd, uint *nextp);
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
};
class sp_instr_cclose : public sp_instr
{
sp_instr_cclose(const sp_instr_cclose &); /**< Prevent use of these */
void operator=(sp_instr_cclose &);
public:
sp_instr_cclose(uint ip, sp_pcontext *ctx, uint c)
: sp_instr(ip, ctx), m_cursor(c)
{}
virtual ~sp_instr_cclose()
{}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
private:
uint m_cursor;
}; // class sp_instr_cclose : public sp_instr
class sp_instr_cfetch : public sp_instr
{
sp_instr_cfetch(const sp_instr_cfetch &); /**< Prevent use of these */
void operator=(sp_instr_cfetch &);
public:
sp_instr_cfetch(uint ip, sp_pcontext *ctx, uint c, bool error_on_no_data)
: sp_instr(ip, ctx), m_cursor(c), m_error_on_no_data(error_on_no_data)
{
m_varlist.empty();
}
virtual ~sp_instr_cfetch()
{}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
void add_to_varlist(sp_variable *var)
{
m_varlist.push_back(var);
}
private:
uint m_cursor;
List<sp_variable> m_varlist;
bool m_error_on_no_data;
}; // class sp_instr_cfetch : public sp_instr
/*
This class is created for the special fetch instruction
FETCH GROUP NEXT ROW, used in the user-defined aggregate
functions
*/
class sp_instr_agg_cfetch : public sp_instr
{
sp_instr_agg_cfetch(const sp_instr_cfetch &); /**< Prevent use of these */
void operator=(sp_instr_cfetch &);
public:
sp_instr_agg_cfetch(uint ip, sp_pcontext *ctx)
: sp_instr(ip, ctx){}
virtual ~sp_instr_agg_cfetch()
{}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
}; // class sp_instr_agg_cfetch : public sp_instr
class sp_instr_error : public sp_instr
{
sp_instr_error(const sp_instr_error &); /**< Prevent use of these */
void operator=(sp_instr_error &);
public:
sp_instr_error(uint ip, sp_pcontext *ctx, int errcode)
: sp_instr(ip, ctx), m_errcode(errcode)
{}
virtual ~sp_instr_error()
{}
virtual int execute(THD *thd, uint *nextp);
virtual void print(String *str);
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads)
{
marked= 1;
return UINT_MAX;
}
private:
int m_errcode;
}; // class sp_instr_error : public sp_instr
class sp_instr_set_case_expr : public sp_instr_opt_meta
{
public:
sp_instr_set_case_expr(uint ip, sp_pcontext *ctx, uint case_expr_id,
Item *case_expr, LEX *lex)
: sp_instr_opt_meta(ip, ctx),
m_case_expr_id(case_expr_id), m_case_expr(case_expr),
m_lex_keeper(lex, TRUE)
{}
virtual ~sp_instr_set_case_expr()
{}
virtual int execute(THD *thd, uint *nextp);
virtual int exec_core(THD *thd, uint *nextp);
virtual void print(String *str);
virtual uint opt_mark(sp_head *sp, List<sp_instr> *leads);
virtual void opt_move(uint dst, List<sp_instr> *ibp);
virtual void set_destination(uint old_dest, uint new_dest)
{
if (m_cont_dest == old_dest)
m_cont_dest= new_dest;
}
private:
uint m_case_expr_id;
Item *m_case_expr;
sp_lex_keeper m_lex_keeper;
}; // class sp_instr_set_case_expr : public sp_instr_opt_meta
bool check_show_routine_access(THD *thd, sp_head *sp, bool *full_access);
#ifndef NO_EMBEDDED_ACCESS_CHECKS
bool
sp_change_security_context(THD *thd, sp_head *sp,
Security_context **backup);
void
sp_restore_security_context(THD *thd, Security_context *backup);
bool
set_routine_security_ctx(THD *thd, sp_head *sp, Security_context **save_ctx);
#endif /* NO_EMBEDDED_ACCESS_CHECKS */
TABLE_LIST *
sp_add_to_query_tables(THD *thd, LEX *lex,
const LEX_CSTRING *db, const LEX_CSTRING *name,
thr_lock_type locktype,
enum_mdl_type mdl_type);
/**
@} (end of group Stored_Routines)
*/
#endif /* _SP_HEAD_H_ */
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