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/* Copyright (c) 2000, 2023, Oracle and/or its affiliates.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License, version 2.0,
as published by the Free Software Foundation.
This program is also distributed with certain software (including
but not limited to OpenSSL) that is licensed under separate terms,
as designated in a particular file or component or in included license
documentation. The authors of MySQL hereby grant you an additional
permission to link the program and your derivative works with the
separately licensed software that they have included with MySQL.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License, version 2.0, for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software Foundation,
51 Franklin Street, Suite 500, Boston, MA 02110-1335 USA */
/*
Single table and multi table updates of tables.
Multi-table updates were introduced by Sinisa & Monty
*/
#include "sql_update.h"
#include "auth_common.h" // check_table_access
#include "binlog.h" // mysql_bin_log
#include "debug_sync.h" // DEBUG_SYNC
#include "field.h" // Field
#include "item.h" // Item
#include "key.h" // is_key_used
#include "opt_explain.h" // Modification_plan
#include "opt_trace.h" // Opt_trace_object
#include "records.h" // READ_RECORD
#include "sql_base.h" // open_tables_for_query
#include "sql_optimizer.h" // build_equal_items, substitute_gc
#include "sql_resolver.h" // setup_order
#include "sql_select.h" // free_underlaid_joins
#include "sql_tmp_table.h" // create_tmp_table
#include "sql_view.h" // check_key_in_view
#include "table.h" // TABLE
#include "table_trigger_dispatcher.h" // Table_trigger_dispatcher
#include "sql_partition.h" // partition_key_modified
#include "sql_prepare.h" // select_like_stmt_cmd_test
#include "probes_mysql.h" // MYSQL_UPDATE_START
#include "sql_parse.h" // all_tables_not_ok
/**
True if the table's input and output record buffers are comparable using
compare_records(TABLE*).
*/
bool records_are_comparable(const TABLE *table) {
return ((table->file->ha_table_flags() & HA_PARTIAL_COLUMN_READ) == 0) ||
bitmap_is_subset(table->write_set, table->read_set);
}
/**
Compares the input and outbut record buffers of the table to see if a row
has changed. The algorithm iterates over updated columns and if they are
nullable compares NULL bits in the buffer before comparing actual
data. Special care must be taken to compare only the relevant NULL bits and
mask out all others as they may be undefined. The storage engine will not
and should not touch them.
@param table The table to evaluate.
@return true if row has changed.
@return false otherwise.
*/
bool compare_records(const TABLE *table)
{
assert(records_are_comparable(table));
if ((table->file->ha_table_flags() & HA_PARTIAL_COLUMN_READ) != 0)
{
/*
Storage engine may not have read all columns of the record. Fields
(including NULL bits) not in the write_set may not have been read and
can therefore not be compared.
*/
for (Field **ptr= table->field ; *ptr != NULL; ptr++)
{
Field *field= *ptr;
if (bitmap_is_set(table->write_set, field->field_index))
{
if (field->real_maybe_null())
{
uchar null_byte_index= field->null_offset();
if (((table->record[0][null_byte_index]) & field->null_bit) !=
((table->record[1][null_byte_index]) & field->null_bit))
return TRUE;
}
if (field->cmp_binary_offset(table->s->rec_buff_length))
return TRUE;
}
}
return FALSE;
}
/*
The storage engine has read all columns, so it's safe to compare all bits
including those not in the write_set. This is cheaper than the field-by-field
comparison done above.
*/
if (table->s->blob_fields + table->s->varchar_fields == 0)
// Fixed-size record: do bitwise comparison of the records
return cmp_record(table,record[1]);
/* Compare null bits */
if (memcmp(table->null_flags,
table->null_flags+table->s->rec_buff_length,
table->s->null_bytes))
return TRUE; // Diff in NULL value
/* Compare updated fields */
for (Field **ptr= table->field ; *ptr ; ptr++)
{
if (bitmap_is_set(table->write_set, (*ptr)->field_index) &&
(*ptr)->cmp_binary_offset(table->s->rec_buff_length))
return TRUE;
}
return FALSE;
}
/**
Check that all fields are base table columns.
Replace columns from views with base table columns, and save original items in
a list for later privilege checking.
@param thd thread handler
@param items Items for check
@param[out] original_columns Saved list of items which are the original
resolved columns (if not NULL)
@return false if success, true if error (Items not updatable columns or OOM)
*/
static bool check_fields(THD *thd, List<Item> &items,
List<Item> *original_columns)
{
List_iterator<Item> it(items);
Item *item;
while ((item= it++))
{
// Save original item for later privilege checking
if (original_columns && original_columns->push_back(item))
return true; /* purecov: inspected */
/*
we make temporary copy of Item_field, to avoid influence of changing
result_field on Item_ref which refer on this field
*/
Item_field *const base_table_field= item->field_for_view_update();
assert(base_table_field != NULL);
Item_field *const cloned_field= new Item_field(thd, base_table_field);
if (!cloned_field)
return true; /* purecov: inspected */
thd->change_item_tree(it.ref(), cloned_field);
}
return false;
}
/**
Check if all expressions in list are constant expressions
@param[in] values List of expressions
@retval true Only constant expressions
@retval false At least one non-constant expression
*/
static bool check_constant_expressions(List<Item> &values)
{
Item *value;
List_iterator_fast<Item> v(values);
DBUG_ENTER("check_constant_expressions");
while ((value= v++))
{
if (!value->const_item())
{
DBUG_PRINT("exit", ("expression is not constant"));
DBUG_RETURN(false);
}
}
DBUG_PRINT("exit", ("expression is constant"));
DBUG_RETURN(true);
}
/**
Prepare a table for an UPDATE operation
@param thd Thread pointer
@param select Query block
@returns false if success, true if error
*/
bool mysql_update_prepare_table(THD *thd, SELECT_LEX *select)
{
TABLE_LIST *const tr= select->table_list.first;
if (!tr->is_view())
return false;
// Semi-join is not possible, as single-table UPDATE does not support joins
if (tr->resolve_derived(thd, false))
return true;
if (select->merge_derived(thd, tr))
return true; /* purecov: inspected */
if (!tr->is_updatable())
{
my_error(ER_NON_UPDATABLE_TABLE, MYF(0), tr->alias, "UPDATE");
return true;
}
return false;
}
/*
Process usual UPDATE
SYNOPSIS
mysql_update()
thd thread handler
fields fields for update
values values of fields for update
limit limit clause
handle_duplicates how to handle duplicates
RETURN
false - OK
true - error
*/
bool mysql_update(THD *thd,
List<Item> &fields,
List<Item> &values,
ha_rows limit,
enum enum_duplicates handle_duplicates,
ha_rows *found_return, ha_rows *updated_return)
{
DBUG_ENTER("mysql_update");
myf error_flags= MYF(0); /**< Flag for fatal errors */
const bool using_limit= limit != HA_POS_ERROR;
bool used_key_is_modified= false;
bool transactional_table, will_batch;
int res;
int error= 1;
int loc_error;
uint used_index, dup_key_found;
bool need_sort= true;
bool reverse= false;
bool using_filesort;
bool read_removal= false;
ha_rows updated, found;
READ_RECORD info;
ulonglong id;
THD::killed_state killed_status= THD::NOT_KILLED;
COPY_INFO update(COPY_INFO::UPDATE_OPERATION, &fields, &values);
SELECT_LEX *const select_lex= thd->lex->select_lex;
TABLE_LIST *const table_list= select_lex->get_table_list();
select_lex->make_active_options(0, 0);
const bool safe_update= thd->variables.option_bits & OPTION_SAFE_UPDATES;
THD_STAGE_INFO(thd, stage_init);
if (!table_list->is_updatable())
{
my_error(ER_NON_UPDATABLE_TABLE, MYF(0), table_list->alias, "UPDATE");
DBUG_RETURN(true);
}
TABLE_LIST *const update_table_ref= table_list->updatable_base_table();
TABLE *const table= update_table_ref->table;
/* Calculate "table->covering_keys" based on the WHERE */
table->covering_keys= table->s->keys_in_use;
table->quick_keys.clear_all();
table->possible_quick_keys.clear_all();
key_map covering_keys_for_cond;
if (mysql_prepare_update(thd, update_table_ref, &covering_keys_for_cond,
values))
DBUG_RETURN(1);
Item *conds;
if (select_lex->get_optimizable_conditions(thd, &conds, NULL))
DBUG_RETURN(1);
if (update.add_function_default_columns(table, table->write_set))
DBUG_RETURN(1);
ORDER *order= select_lex->order_list.first;
/*
See if we can substitute expressions with equivalent generated
columns in the WHERE and ORDER BY clauses of the UPDATE statement.
It is unclear if this is best to do before or after the other
substitutions performed by substitute_for_best_equal_field(). Do
it here for now, to keep it consistent with how multi-table
updates are optimized in JOIN::optimize().
*/
if (conds || order)
static_cast<void>(substitute_gc(thd, select_lex, conds, NULL, order));
if ((table->file->ha_table_flags() & HA_PARTIAL_COLUMN_READ) != 0 &&
update.function_defaults_apply(table))
/*
A column is to be set to its ON UPDATE function default only if other
columns of the row are changing. To know this, we must be able to
compare the "before" and "after" value of those columns
(i.e. records_are_comparable() must be true below). Thus, we must read
those columns:
*/
bitmap_union(table->read_set, table->write_set);
// Don't count on usage of 'only index' when calculating which key to use
table->covering_keys.clear_all();
/*
This must be done before partitioning pruning, since prune_partitions()
uses the table->write_set to determine may prune locks too.
*/
if (table->triggers && table->triggers->mark_fields(TRG_EVENT_UPDATE))
DBUG_RETURN(true);
QEP_TAB_standalone qep_tab_st;
QEP_TAB &qep_tab= qep_tab_st.as_QEP_TAB();
if (table->part_info)
{
if (prune_partitions(thd, table, conds))
DBUG_RETURN(1);
if (table->all_partitions_pruned_away)
{
/* No matching records */
if (thd->lex->describe)
{
/*
Initialize plan only for regular EXPLAIN. Don't do it for EXPLAIN
FOR CONNECTION as the plan would exist for very short period of time
but will cost taking/releasing of a mutex, so it's not worth
bothering with. Same for similar cases below.
*/
Modification_plan plan(thd, MT_UPDATE, table,
"No matching rows after partition pruning",
true, 0);
error= explain_single_table_modification(thd, &plan, select_lex);
goto exit_without_my_ok;
}
my_ok(thd);
DBUG_RETURN(0);
}
}
if (lock_tables(thd, table_list, thd->lex->table_count, 0))
DBUG_RETURN(1);
// Must be done after lock_tables()
if (conds)
{
COND_EQUAL *cond_equal= NULL;
Item::cond_result result;
if (table_list->check_option)
{
/*
If this UPDATE is on a view with CHECK OPTION, Item_fields
must not be replaced by constants. The reason is that when
'conds' is optimized, 'check_option' is also optimized (it is
part of 'conds'). Const replacement is fine for 'conds'
because it is evaluated on a read row, but 'check_option' is
evaluated on a row with updated fields and needs those updated
values to be correct.
Example:
CREATE VIEW v1 ... WHERE fld < 2 WITH CHECK_OPTION
UPDATE v1 SET fld=4 WHERE fld=1
check_option is "(fld < 2)"
conds is "(fld < 2) and (fld = 1)"
optimize_cond() would propagate fld=1 to the first argument of
the AND to create "(1 < 2) AND (fld = 1)". After this,
check_option would be "(1 < 2)". But for check_option to work
it must be evaluated with the *updated* value of fld: 4.
Otherwise it will evaluate to true even when it should be
false, which is the case for the UPDATE statement above.
Thus, if there is a check_option, we do only the "safe" parts
of optimize_cond(): Item_row -> Item_func_eq conversion (to
enable range access) and removal of always true/always false
predicates.
An alternative to restricting this optimization of 'conds' in
the presense of check_option: the Item-tree of 'check_option'
could be cloned before optimizing 'conds' and thereby avoid
const replacement. However, at the moment there is no such
thing as Item::clone().
*/
if (build_equal_items(thd, conds, &conds, NULL, false,
select_lex->join_list, &cond_equal))
goto exit_without_my_ok;
if (remove_eq_conds(thd, conds, &conds, &result))
goto exit_without_my_ok;
}
else
{
if (optimize_cond(thd, &conds, &cond_equal, select_lex->join_list,
&result))
goto exit_without_my_ok;
}
if (result == Item::COND_FALSE)
{
limit= 0; // Impossible WHERE
if (thd->lex->describe)
{
Modification_plan plan(thd, MT_UPDATE, table,
"Impossible WHERE", true, 0);
error= explain_single_table_modification(thd, &plan, select_lex);
goto exit_without_my_ok;
}
}
if (conds)
{
conds= substitute_for_best_equal_field(conds, cond_equal, 0);
if (conds == NULL)
{
error= true;
goto exit_without_my_ok;
}
conds->update_used_tables();
}
}
/*
Also try a second time after locking, to prune when subqueries and
stored programs can be evaluated.
*/
if (table->part_info)
{
if (prune_partitions(thd, table, conds))
DBUG_RETURN(1);
if (table->all_partitions_pruned_away)
{
if (thd->lex->describe)
{
Modification_plan plan(thd, MT_UPDATE, table,
"No matching rows after partition pruning",
true, 0);
error= explain_single_table_modification(thd, &plan, select_lex);
goto exit_without_my_ok;
}
my_ok(thd);
DBUG_RETURN(0);
}
}
// Initialize the cost model that will be used for this table
table->init_cost_model(thd->cost_model());
/* Update the table->file->stats.records number */
table->file->info(HA_STATUS_VARIABLE | HA_STATUS_NO_LOCK);
table->mark_columns_needed_for_update(false/*mark_binlog_columns=false*/);
if (table->vfield &&
validate_gc_assignment(thd, &fields, &values, table))
DBUG_RETURN(0);
error= 0;
qep_tab.set_table(table);
qep_tab.set_condition(conds);
{ // Enter scope for optimizer trace wrapper
Opt_trace_object wrapper(&thd->opt_trace);
wrapper.add_utf8_table(update_table_ref);
bool impossible= false;
if (error || limit == 0)
impossible= true;
else if (conds != NULL)
{
key_map keys_to_use(key_map::ALL_BITS), needed_reg_dummy;
QUICK_SELECT_I *qck;
impossible= test_quick_select(thd, keys_to_use, 0, limit, safe_update,
ORDER::ORDER_NOT_RELEVANT, &qep_tab,
conds, &needed_reg_dummy, &qck,
qep_tab.table()->force_index) < 0;
qep_tab.set_quick(qck);
}
if (impossible)
{
if (thd->lex->describe && !error && !thd->is_error())
{
Modification_plan plan(thd, MT_UPDATE, table,
"Impossible WHERE", true, 0);
error= explain_single_table_modification(thd, &plan, select_lex);
goto exit_without_my_ok;
}
free_underlaid_joins(thd, select_lex);
/*
There was an error or the error was already sent by
the quick select evaluation.
TODO: Add error code output parameter to Item::val_xxx() methods.
Currently they rely on the user checking DA for
errors when unwinding the stack after calling Item::val_xxx().
*/
if (error || thd->is_error())
{
DBUG_RETURN(1); // Error in where
}
char buff[MYSQL_ERRMSG_SIZE];
my_snprintf(buff, sizeof(buff), ER(ER_UPDATE_INFO), 0, 0,
(long) thd->get_stmt_da()->current_statement_cond_count());
my_ok(thd, 0, 0, buff);
DBUG_PRINT("info",("0 records updated"));
DBUG_RETURN(0);
}
} // Ends scope for optimizer trace wrapper
/* If running in safe sql mode, don't allow updates without keys */
if (table->quick_keys.is_clear_all())
{
thd->server_status|= SERVER_QUERY_NO_INDEX_USED;
/*
No safe update error will be returned if:
1) Statement is an EXPLAIN OR
2) LIMIT is present.
Append the first warning (if any) to the error message. Allows the user
to understand why index access couldn't be chosen.
*/
if (!thd->lex->is_explain() && safe_update && !using_limit)
{
my_error(ER_UPDATE_WITHOUT_KEY_IN_SAFE_MODE, MYF(0),
thd->get_stmt_da()->get_first_condition_message());
DBUG_RETURN(true);
}
}
if (select_lex->has_ft_funcs() && init_ftfuncs(thd, select_lex))
goto exit_without_my_ok;
table->update_const_key_parts(conds);
order= simple_remove_const(order, conds);
used_index= get_index_for_order(order, &qep_tab, limit,
&need_sort, &reverse);
if (need_sort)
{ // Assign table scan index to check below for modified key fields:
used_index= table->file->key_used_on_scan;
}
if (used_index != MAX_KEY)
{ // Check if we are modifying a key that we are used to search with:
used_key_is_modified= is_key_used(table, used_index, table->write_set);
}
else if (qep_tab.quick())
{
/*
select->quick != NULL and used_index == MAX_KEY happens for index
merge and should be handled in a different way.
*/
used_key_is_modified= (!qep_tab.quick()->unique_key_range() &&
qep_tab.quick()->is_keys_used(table->write_set));
}
used_key_is_modified|= partition_key_modified(table, table->write_set);
table->mark_columns_per_binlog_row_image();
using_filesort= order && need_sort;
{
ha_rows rows;
if (qep_tab.quick())
rows= qep_tab.quick()->records;
else if (!conds && !need_sort && limit != HA_POS_ERROR)
rows= limit;
else
{
assert(table->pos_in_table_list == update_table_ref);
update_table_ref->fetch_number_of_rows();
rows= table->file->stats.records;
}
qep_tab.set_quick_optim();
qep_tab.set_condition_optim();
DEBUG_SYNC(thd, "before_single_update");
Modification_plan plan(thd, MT_UPDATE, &qep_tab,
used_index, limit,
(!using_filesort && (used_key_is_modified || order)),
using_filesort, used_key_is_modified, rows);
DEBUG_SYNC(thd, "planned_single_update");
if (thd->lex->describe)
{
error= explain_single_table_modification(thd, &plan, select_lex);
goto exit_without_my_ok;
}
if (used_key_is_modified || order)
{
/*
We can't update table directly; We must first search after all
matching rows before updating the table!
*/
if (used_index < MAX_KEY && covering_keys_for_cond.is_set(used_index))
table->set_keyread(true);
/* note: We avoid sorting if we sort on the used index */
if (using_filesort)
{
/*
Doing an ORDER BY; Let filesort find and sort the rows we are going
to update
NOTE: filesort will call table->prepare_for_position()
*/
ha_rows examined_rows, found_rows, returned_rows;
Filesort fsort(&qep_tab, order, limit);
assert(table->sort.io_cache == NULL);
table->sort.io_cache= (IO_CACHE*) my_malloc(key_memory_TABLE_sort_io_cache,
sizeof(IO_CACHE),
MYF(MY_FAE | MY_ZEROFILL));
if (filesort(thd, &fsort, true,
&examined_rows, &found_rows, &returned_rows))
goto exit_without_my_ok;
table->sort.found_records= returned_rows;
thd->inc_examined_row_count(examined_rows);
/*
Filesort has already found and selected the rows we want to update,
so we don't need the where clause
*/
qep_tab.set_quick(NULL);
qep_tab.set_condition(NULL);
}
else
{
/*
We are doing a search on a key that is updated. In this case
we go trough the matching rows, save a pointer to them and
update these in a separate loop based on the pointer.
*/
table->prepare_for_position();
/* If quick select is used, initialize it before retrieving rows. */
if (qep_tab.quick() && (error= qep_tab.quick()->reset()))
{
if (table->file->is_fatal_error(error))
error_flags|= ME_FATALERROR;
table->file->print_error(error, error_flags);
goto exit_without_my_ok;
}
table->file->try_semi_consistent_read(1);
/*
When we get here, we have one of the following options:
A. used_index == MAX_KEY
This means we should use full table scan, and start it with
init_read_record call
B. used_index != MAX_KEY
B.1 quick select is used, start the scan with init_read_record
B.2 quick select is not used, this is full index scan (with LIMIT)
Full index scan must be started with init_read_record_idx
*/
if (used_index == MAX_KEY || (qep_tab.quick()))
error= init_read_record(&info, thd, NULL, &qep_tab, 0, 1, FALSE);
else
error= init_read_record_idx(&info, thd, table, 1, used_index, reverse);
if (error)
goto exit_without_my_ok;
THD_STAGE_INFO(thd, stage_searching_rows_for_update);
ha_rows tmp_limit= limit;
IO_CACHE *tempfile= (IO_CACHE*) my_malloc(key_memory_TABLE_sort_io_cache,
sizeof(IO_CACHE),
MYF(MY_FAE | MY_ZEROFILL));
if (open_cached_file(tempfile, mysql_tmpdir,TEMP_PREFIX,
DISK_BUFFER_SIZE, MYF(MY_WME)))
{
my_free(tempfile);
goto exit_without_my_ok;
}
while (!(error=info.read_record(&info)) && !thd->killed)
{
thd->inc_examined_row_count(1);
bool skip_record= FALSE;
if (qep_tab.skip_record(thd, &skip_record))
{
error= 1;
/*
Don't try unlocking the row if skip_record reported an error since
in this case the transaction might have been rolled back already.
*/
break;
}
if (!skip_record)
{
if (table->file->was_semi_consistent_read())
continue; /* repeat the read of the same row if it still exists */
table->file->position(table->record[0]);
if (my_b_write(tempfile, table->file->ref,
table->file->ref_length))
{
error=1; /* purecov: inspected */
break; /* purecov: inspected */
}
if (!--limit && using_limit)
{
error= -1;
break;
}
}
else
table->file->unlock_row();
}
if (thd->killed && !error) // Aborted
error= 1; /* purecov: inspected */
limit= tmp_limit;
table->file->try_semi_consistent_read(0);
end_read_record(&info);
/* Change select to use tempfile */
if (reinit_io_cache(tempfile, READ_CACHE, 0L, 0, 0))
error=1; /* purecov: inspected */
assert(table->sort.io_cache == NULL);
/*
After this assignment, init_read_record() will run, and decide to
read from sort.io_cache. This cache will be freed when qep_tab is
destroyed.
*/
table->sort.io_cache= tempfile;
qep_tab.set_quick(NULL);
qep_tab.set_condition(NULL);
if (error >= 0)
goto exit_without_my_ok;
}
if (used_index < MAX_KEY && covering_keys_for_cond.is_set(used_index))
table->set_keyread(false);
table->file->ha_index_or_rnd_end();
}
if (thd->lex->is_ignore())
table->file->extra(HA_EXTRA_IGNORE_DUP_KEY);
if (qep_tab.quick() && (error= qep_tab.quick()->reset()))
{
if (table->file->is_fatal_error(error))
error_flags|= ME_FATALERROR;
table->file->print_error(error, error_flags);
goto exit_without_my_ok;
}
table->file->try_semi_consistent_read(1);
if ((error= init_read_record(&info, thd, NULL, &qep_tab, 0, 1, FALSE)))
goto exit_without_my_ok;
updated= found= 0;
/*
Generate an error (in TRADITIONAL mode) or warning
when trying to set a NOT NULL field to NULL.
*/
thd->count_cuted_fields= CHECK_FIELD_WARN;
thd->cuted_fields=0L;
THD_STAGE_INFO(thd, stage_updating);
transactional_table= table->file->has_transactions();
if (table->triggers &&
table->triggers->has_triggers(TRG_EVENT_UPDATE,
TRG_ACTION_AFTER))
{
/*
The table has AFTER UPDATE triggers that might access to subject
table and therefore might need update to be done immediately.
So we turn-off the batching.
*/
(void) table->file->extra(HA_EXTRA_UPDATE_CANNOT_BATCH);
will_batch= FALSE;
}
else
will_batch= !table->file->start_bulk_update();
if ((table->file->ha_table_flags() & HA_READ_BEFORE_WRITE_REMOVAL) &&
!thd->lex->is_ignore() && !using_limit &&
!(table->triggers && table->triggers->has_update_triggers()) &&
qep_tab.quick() && qep_tab.quick()->index != MAX_KEY &&
check_constant_expressions(values))
read_removal= table->check_read_removal(qep_tab.quick()->index);
while (true)
{
error= info.read_record(&info);
if (error || thd->killed)
break;
thd->inc_examined_row_count(1);
bool skip_record;
if ((!qep_tab.skip_record(thd, &skip_record) && !skip_record))
{
if (table->file->was_semi_consistent_read())
continue; /* repeat the read of the same row if it still exists */
store_record(table,record[1]);
if (fill_record_n_invoke_before_triggers(thd, &update, fields, values,
table, TRG_EVENT_UPDATE, 0))
break; /* purecov: inspected */
found++;
if (!records_are_comparable(table) || compare_records(table))
{
if ((res= table_list->view_check_option(thd)) != VIEW_CHECK_OK)
{
found--;
if (res == VIEW_CHECK_SKIP)
continue;
else if (res == VIEW_CHECK_ERROR)
{
error= 1;
break;
}
}
/*
In order to keep MySQL legacy behavior, we do this update *after*
the CHECK OPTION test. Proper behavior is probably to throw an
error, though.
*/
update.set_function_defaults(table);
if (will_batch)
{
/*
Typically a batched handler can execute the batched jobs when:
1) When specifically told to do so
2) When it is not a good idea to batch anymore
3) When it is necessary to send batch for other reasons
(One such reason is when READ's must be performed)
1) is covered by exec_bulk_update calls.
2) and 3) is handled by the bulk_update_row method.
bulk_update_row can execute the updates including the one
defined in the bulk_update_row or not including the row
in the call. This is up to the handler implementation and can
vary from call to call.
The dup_key_found reports the number of duplicate keys found
in those updates actually executed. It only reports those if
the extra call with HA_EXTRA_IGNORE_DUP_KEY have been issued.
If this hasn't been issued it returns an error code and can
ignore this number. Thus any handler that implements batching
for UPDATE IGNORE must also handle this extra call properly.
If a duplicate key is found on the record included in this
call then it should be included in the count of dup_key_found
and error should be set to 0 (only if these errors are ignored).
*/
error= table->file->ha_bulk_update_row(table->record[1],
table->record[0],
&dup_key_found);
limit+= dup_key_found;
updated-= dup_key_found;
}
else
{
/* Non-batched update */
error= table->file->ha_update_row(table->record[1],
table->record[0]);
}
if (error == 0)
updated++;
else if (error == HA_ERR_RECORD_IS_THE_SAME)
error= 0;
else
{
if (table->file->is_fatal_error(error))
error_flags|= ME_FATALERROR;
table->file->print_error(error, error_flags);
// The error can have been downgraded to warning by IGNORE.
if (thd->is_error())
break;
}
}
else
{
/*
Some no operation dml statements do not go through SE.
In read_only mode, if a no operation dml is not marked as
read_write then binlogging cant be restricted for that statement.
To make binlogging be consistent in read_only mode,
if the no operation dml statement doesn't go through SE then mark
that statement as noop_read_write here.
*/
table->file->mark_trx_noop_dml();
}
if (!error && table->triggers &&
table->triggers->process_triggers(thd, TRG_EVENT_UPDATE,
TRG_ACTION_AFTER, TRUE))
{
error= 1;
break;
}
if (!--limit && using_limit)
{
/*
We have reached end-of-file in most common situations where no
batching has occurred and if batching was supposed to occur but
no updates were made and finally when the batch execution was
performed without error and without finding any duplicate keys.
If the batched updates were performed with errors we need to
check and if no error but duplicate key's found we need to
continue since those are not counted for in limit.
*/
if (will_batch &&
((error= table->file->exec_bulk_update(&dup_key_found)) ||
dup_key_found))
{
if (error)
{
/* purecov: begin inspected */
/*
The handler should not report error of duplicate keys if they
are ignored. This is a requirement on batching handlers.
*/
if (table->file->is_fatal_error(error))
error_flags|= ME_FATALERROR;
table->file->print_error(error, error_flags);
error= 1;
break;
/* purecov: end */
}
/*
Either an error was found and we are ignoring errors or there
were duplicate keys found. In both cases we need to correct
the counters and continue the loop.
*/
limit= dup_key_found; //limit is 0 when we get here so need to +
updated-= dup_key_found;
}
else
{
error= -1; // Simulate end of file
break;
}
}
}
/*
Don't try unlocking the row if skip_record reported an error since in
this case the transaction might have been rolled back already.
*/
else if (!thd->is_error())
table->file->unlock_row();
else
{
error= 1;
break;
}
thd->get_stmt_da()->inc_current_row_for_condition();
if (thd->is_error())
{
error= 1;
break;
}
}
table->auto_increment_field_not_null= FALSE;
dup_key_found= 0;
/*
Caching the killed status to pass as the arg to query event constuctor;
The cached value can not change whereas the killed status can
(externally) since this point and change of the latter won't affect
binlogging.
It's assumed that if an error was set in combination with an effective
killed status then the error is due to killing.
*/
killed_status= thd->killed; // get the status of the volatile
// simulated killing after the loop must be ineffective for binlogging
DBUG_EXECUTE_IF("simulate_kill_bug27571",
{
thd->killed= THD::KILL_QUERY;
};);
error= (killed_status == THD::NOT_KILLED)? error : 1;
if (error &&
will_batch &&
(loc_error= table->file->exec_bulk_update(&dup_key_found)))
/*
An error has occurred when a batched update was performed and returned
an error indication. It cannot be an allowed duplicate key error since
we require the batching handler to treat this as a normal behavior.
Otherwise we simply remove the number of duplicate keys records found
in the batched update.
*/
{
/* purecov: begin inspected */
error_flags= MYF(0);
if (table->file->is_fatal_error(loc_error))
error_flags|= ME_FATALERROR;
table->file->print_error(loc_error, error_flags);
error= 1;
/* purecov: end */
}
else
updated-= dup_key_found;
if (will_batch)
table->file->end_bulk_update();
table->file->try_semi_consistent_read(0);
if (read_removal)
{
/* Only handler knows how many records really was written */
updated= table->file->end_read_removal();
if (!records_are_comparable(table))
found= updated;
}
} // End of scope for Modification_plan
if (!transactional_table && updated > 0)
thd->get_transaction()->mark_modified_non_trans_table(
Transaction_ctx::STMT);
end_read_record(&info);
THD_STAGE_INFO(thd, stage_end);
(void) table->file->extra(HA_EXTRA_NO_IGNORE_DUP_KEY);
/*
Invalidate the table in the query cache if something changed.
This must be before binlog writing and ha_autocommit_...
*/
if (updated)
query_cache.invalidate_single(thd, update_table_ref, true);
/*
error < 0 means really no error at all: we processed all rows until the
last one without error. error > 0 means an error (e.g. unique key
violation and no IGNORE or REPLACE). error == 0 is also an error (if
preparing the record or invoking before triggers fails). See
ha_autocommit_or_rollback(error>=0) and DBUG_RETURN(error>=0) below.
Sometimes we want to binlog even if we updated no rows, in case user used
it to be sure master and slave are in same state.
*/
if ((error < 0) || thd->get_transaction()->cannot_safely_rollback(
Transaction_ctx::STMT))
{
if (mysql_bin_log.is_open())
{
int errcode= 0;
if (error < 0)
thd->clear_error();
else
errcode= query_error_code(thd, killed_status == THD::NOT_KILLED);
if (thd->binlog_query(THD::ROW_QUERY_TYPE,
thd->query().str, thd->query().length,
transactional_table, FALSE, FALSE, errcode))
{
error=1; // Rollback update
}
}
}
assert(transactional_table || !updated ||
thd->get_transaction()->cannot_safely_rollback(
Transaction_ctx::STMT));
free_underlaid_joins(thd, select_lex);
/* If LAST_INSERT_ID(X) was used, report X */
id= thd->arg_of_last_insert_id_function ?
thd->first_successful_insert_id_in_prev_stmt : 0;
if (error < 0)
{
char buff[MYSQL_ERRMSG_SIZE];
my_snprintf(buff, sizeof(buff), ER(ER_UPDATE_INFO), (long) found,
(long) updated,
(long) thd->get_stmt_da()->current_statement_cond_count());
my_ok(thd, thd->get_protocol()->has_client_capability(CLIENT_FOUND_ROWS) ?
found : updated, id, buff);
DBUG_PRINT("info",("%ld records updated", (long) updated));
}
thd->count_cuted_fields= CHECK_FIELD_IGNORE; /* calc cuted fields */
*found_return= found;
*updated_return= updated;
DBUG_RETURN((error >= 0 || thd->is_error()) ? 1 : 0);
exit_without_my_ok:
free_underlaid_joins(thd, select_lex);
table->set_keyread(FALSE);
DBUG_RETURN(error);
}
/**
Prepare items in UPDATE statement
@param thd thread handler
@param update_table_ref Reference to table being updated
@param[out] covering_keys_for_cond Keys which are covering for conditions
and ORDER BY clause.
@return false if success, true if error
*/
bool mysql_prepare_update(THD *thd, const TABLE_LIST *update_table_ref,
key_map *covering_keys_for_cond,
List<Item> &update_value_list)
{
List<Item> all_fields;
LEX *const lex= thd->lex;
SELECT_LEX *const select= lex->select_lex;
TABLE_LIST *const table_list= select->get_table_list();
DBUG_ENTER("mysql_prepare_update");
assert(select->item_list.elements == update_value_list.elements);
lex->allow_sum_func= 0;
if (select->setup_tables(thd, table_list, false))
DBUG_RETURN(true);
if (select->derived_table_count &&
select->check_view_privileges(thd, UPDATE_ACL, SELECT_ACL))
DBUG_RETURN(true);
thd->want_privilege= SELECT_ACL;
enum enum_mark_columns mark_used_columns_saved= thd->mark_used_columns;
thd->mark_used_columns= MARK_COLUMNS_READ;
#ifndef NO_EMBEDDED_ACCESS_CHECKS
table_list->set_want_privilege(SELECT_ACL);
#endif
if (select->setup_conds(thd))
DBUG_RETURN(true);
if (select->setup_ref_array(thd))
DBUG_RETURN(true); /* purecov: inspected */
if (select->order_list.first &&
setup_order(thd, select->ref_pointer_array,
table_list, all_fields, all_fields,
select->order_list.first))
DBUG_RETURN(true);
// Return covering keys derived from conditions and ORDER BY clause:
*covering_keys_for_cond= update_table_ref->table->covering_keys;
// Check the fields we are going to modify
#ifndef NO_EMBEDDED_ACCESS_CHECKS
table_list->set_want_privilege(UPDATE_ACL);
#endif
if (setup_fields(thd, Ref_ptr_array(), select->item_list, UPDATE_ACL, NULL,
false, true))
DBUG_RETURN(true); /* purecov: inspected */
if (check_fields(thd, select->item_list, NULL))
DBUG_RETURN(true);
// check_key_in_view() may send an SQL note, but we only want it once.
if (select->first_execution &&
check_key_in_view(thd, table_list, update_table_ref))
{
my_error(ER_NON_UPDATABLE_TABLE, MYF(0), table_list->alias, "UPDATE");
DBUG_RETURN(true);
}
table_list->set_want_privilege(SELECT_ACL);
if (setup_fields(thd, Ref_ptr_array(), update_value_list, SELECT_ACL, NULL,
false, false))
DBUG_RETURN(true); /* purecov: inspected */
thd->mark_used_columns= mark_used_columns_saved;
// Check that table to be updated is not used in a subquery
TABLE_LIST *const duplicate= unique_table(thd, update_table_ref,
table_list->next_global, 0);
if (duplicate)
{
update_non_unique_table_error(table_list, "UPDATE", duplicate);
DBUG_RETURN(true);
}
if (setup_ftfuncs(select))
DBUG_RETURN(true); /* purecov: inspected */
if (select->inner_refs_list.elements && select->fix_inner_refs(thd))
DBUG_RETURN(true); /* purecov: inspected */
if (select->apply_local_transforms(thd, false))
DBUG_RETURN(true);
DBUG_RETURN(false);
}
/***************************************************************************
Update multiple tables from join
***************************************************************************/
/*
Get table map for list of Item_field
*/
static table_map get_table_map(List<Item> *items)
{
List_iterator_fast<Item> item_it(*items);
Item_field *item;
table_map map= 0;
while ((item= (Item_field *) item_it++))
map|= item->used_tables();
DBUG_PRINT("info", ("table_map: 0x%08lx", (long) map));
return map;
}
/**
If one row is updated through two different aliases and the first
update physically moves the row, the second update will error
because the row is no longer located where expected. This function
checks if the multiple-table update is about to do that and if so
returns with an error.
The following update operations physically moves rows:
1) Update of a column in a clustered primary key
2) Update of a column used to calculate which partition the row belongs to
This function returns with an error if both of the following are
true:
a) A table in the multiple-table update statement is updated
through multiple aliases (including views)
b) At least one of the updates on the table from a) may physically
moves the row. Note: Updating a column used to calculate which
partition a row belongs to does not necessarily mean that the
row is moved. The new value may or may not belong to the same
partition.
@param leaves First leaf table
@param tables_for_update Map of tables that are updated
@return
true if the update is unsafe, in which case an error message is also set,
false otherwise.
*/
static
bool unsafe_key_update(TABLE_LIST *leaves, table_map tables_for_update)
{
TABLE_LIST *tl= leaves;
for (tl= leaves; tl ; tl= tl->next_leaf)
{
if (tl->map() & tables_for_update)
{
TABLE *table1= tl->table;
bool primkey_clustered= (table1->file->primary_key_is_clustered() &&
table1->s->primary_key != MAX_KEY);
bool table_partitioned= (table1->part_info != NULL);
if (!table_partitioned && !primkey_clustered)
continue;
for (TABLE_LIST* tl2= tl->next_leaf; tl2 ; tl2= tl2->next_leaf)
{
/*
Look at "next" tables only since all previous tables have
already been checked
*/
TABLE *table2= tl2->table;
if (tl2->map() & tables_for_update && table1->s == table2->s)
{
// A table is updated through two aliases
if (table_partitioned &&
(partition_key_modified(table1, table1->write_set) ||
partition_key_modified(table2, table2->write_set)))
{
// Partitioned key is updated
my_error(ER_MULTI_UPDATE_KEY_CONFLICT, MYF(0),
tl->belong_to_view ? tl->belong_to_view->alias
: tl->alias,
tl2->belong_to_view ? tl2->belong_to_view->alias
: tl2->alias);
return true;
}
if (primkey_clustered)
{
// The primary key can cover multiple columns
KEY key_info= table1->key_info[table1->s->primary_key];
KEY_PART_INFO *key_part= key_info.key_part;
KEY_PART_INFO *key_part_end= key_part +
key_info.user_defined_key_parts;
for (;key_part != key_part_end; ++key_part)
{
if (bitmap_is_set(table1->write_set, key_part->fieldnr-1) ||
bitmap_is_set(table2->write_set, key_part->fieldnr-1))
{
// Clustered primary key is updated
my_error(ER_MULTI_UPDATE_KEY_CONFLICT, MYF(0),
tl->belong_to_view ? tl->belong_to_view->alias
: tl->alias,
tl2->belong_to_view ? tl2->belong_to_view->alias
: tl2->alias);
return true;
}
}
}
}
}
}
}
return false;
}
/**
Check if there is enough privilege on specific table used by the
main select list of multi-update directly or indirectly (through
a view).
@param[in] thd Thread context.
@param[in] table Table list element for the table.
@param[in] tables_for_update Bitmap with tables being updated.
@param[in] updatable True if table in question is updatable.
Should be initialized to true by the caller
before a sequence of calls to this function.
@param[out] updated Return whether the table is actually updated.
Should be initialized to false by caller.
@note To determine which tables/views are updated we have to go from
leaves to root since tables_for_update contains map of leaf
tables being updated and doesn't include non-leaf tables
(fields are already resolved to leaf tables).
@retval false - Success, all necessary privileges on all tables are
present or might be present on column-level.
@retval true - Failure, some necessary privilege on some table is
missing.
*/
static bool multi_update_check_table_access(THD *thd, TABLE_LIST *table,
table_map tables_for_update,
bool updatable, bool *updated)
{
// Adjust updatability based on table/view's properties:
updatable&= table->is_updatable();
if (table->is_view_or_derived())
{
// Determine if this view/derived table is updated:
bool view_updated= false;
/*
If it is a mergeable view then we need to check privileges on its
underlying tables being merged (including views). We also need to
check if any of them is updated in order to find if this view is
updated.
If it is a non-mergeable view or a derived table then it can't be updated.
*/
assert(table->merge_underlying_list ||
(!table->is_updatable() &&
!(table->map() & tables_for_update)));
Internal_error_handler_holder<View_error_handler, TABLE_LIST>
view_handler(thd, true, table->merge_underlying_list);
for (TABLE_LIST *tbl= table->merge_underlying_list; tbl;
tbl= tbl->next_local)
{
if (multi_update_check_table_access(thd, tbl, tables_for_update,
updatable, &view_updated))
return true;
}
table->set_want_privilege(
view_updated ? UPDATE_ACL | SELECT_ACL: SELECT_ACL);
table->updating= view_updated;
*updated|= view_updated;
}
else
{
// Must be a base table.
const bool base_table_updated= table->map() & tables_for_update;
if (base_table_updated && !updatable)
{
my_error(ER_NON_UPDATABLE_TABLE, MYF(0), table->alias, "UPDATE");
return true;
}
table->set_want_privilege(
base_table_updated ? UPDATE_ACL | SELECT_ACL : SELECT_ACL);
table->updating= base_table_updated;
*updated|= base_table_updated;
}
return false;
}
/*
make update specific preparation and checks after opening tables
SYNOPSIS
mysql_multi_update_prepare()
thd thread handler
RETURN
FALSE OK
TRUE Error
*/
int Sql_cmd_update::mysql_multi_update_prepare(THD *thd)
{
LEX *lex= thd->lex;
SELECT_LEX *select= lex->select_lex;
TABLE_LIST *table_list= lex->query_tables;
List<Item> *fields= &select->item_list;
table_map tables_for_update;
const bool using_lock_tables= thd->locked_tables_mode != LTM_NONE;
bool original_multiupdate= (thd->lex->sql_command == SQLCOM_UPDATE_MULTI);
DBUG_ENTER("mysql_multi_update_prepare");
assert(select->item_list.elements == update_value_list.elements);
Prepare_error_tracker tracker(thd);
/* following need for prepared statements, to run next time multi-update */
sql_command= thd->lex->sql_command= SQLCOM_UPDATE_MULTI;
/*
Open tables and create derived ones, but do not lock and fill them yet.
During prepare phase acquire only S metadata locks instead of SW locks to
keep prepare of multi-UPDATE compatible with concurrent LOCK TABLES WRITE
and global read lock.
*/
if (original_multiupdate &&
open_tables_for_query(thd, table_list,
thd->stmt_arena->is_stmt_prepare() ?
MYSQL_OPEN_FORCE_SHARED_MDL : 0))
DBUG_RETURN(true);
if (run_before_dml_hook(thd))
DBUG_RETURN(true);
/*
setup_tables() need for VIEWs. SELECT_LEX::prepare() will call
setup_tables() second time, but this call will do nothing (there are check
for second call in setup_tables()).
*/
if (select->setup_tables(thd, table_list, false))
DBUG_RETURN(true); /* purecov: inspected */
/*
A view's CHECK OPTION is incompatible with semi-join.
@note We could let non-updated views do semi-join, and we could let
updated views without CHECK OPTION do semi-join.
But since we resolve derived tables before we know this context,
we cannot use semi-join in any case currently.
The problem is that the CHECK OPTION condition serves as
part of the semi-join condition, and a standalone condition
to be evaluated as part of the UPDATE, and those two uses are
incompatible.
*/
if (select->derived_table_count && select->resolve_derived(thd, false))
DBUG_RETURN(true);
if (setup_natural_join_row_types(thd, select->join_list, &select->context))
DBUG_RETURN(true);
/*
In multi-table UPDATE, tables to be updated are determined based on
which fields are updated. Hence, tables that need to be checked
for update have not been established yet, and thus 0 is supplied
for want_privilege argument below.
Later, the combined used_tables information for these columns are used
to determine updatable tables, those tables are prepared for update,
and finally the columns can be checked for proper update privileges.
*/
if (setup_fields(thd, Ref_ptr_array(), *fields, 0, NULL, false, true))
DBUG_RETURN(true);
List<Item> original_update_fields;
if (check_fields(thd, *fields, &original_update_fields))
DBUG_RETURN(true);
thd->table_map_for_update= tables_for_update= get_table_map(fields);
/*
Setup timestamp handling and locking mode
*/
for (TABLE_LIST *tl= select->leaf_tables; tl; tl= tl->next_leaf)
{
// if table will be updated then check that it is updatable and unique:
if (tl->map() & tables_for_update)
{
if (!tl->is_updatable() || check_key_in_view(thd, tl, tl))
{
my_error(ER_NON_UPDATABLE_TABLE, MYF(0), tl->alias, "UPDATE");
DBUG_RETURN(true);
}
DBUG_PRINT("info",("setting table `%s` for update", tl->alias));
/*
If table will be updated we should not downgrade lock for it and
leave it as is.
*/
}
else
{
DBUG_PRINT("info",("setting table `%s` for read-only", tl->alias));
/*
If we are using the binary log, we need TL_READ_NO_INSERT to get
correct order of statements. Otherwise, we use a TL_READ lock to
improve performance.
We don't downgrade metadata lock from SW to SR in this case as
there is no guarantee that the same ticket is not used by
another table instance used by this statement which is going to
be write-locked (for example, trigger to be invoked might try
to update this table).
Last argument routine_modifies_data for read_lock_type_for_table()
is ignored, as prelocking placeholder will never be set here.
*/
assert(tl->prelocking_placeholder == false);
tl->lock_type= read_lock_type_for_table(thd, lex, tl, true);
/* Update TABLE::lock_type accordingly. */
if (!tl->is_placeholder() && !using_lock_tables)
tl->table->reginfo.lock_type= tl->lock_type;
}
}
/*
Check privileges for tables being updated or read.
Note that we need to iterate here not only through all leaf tables but
also through all view hierarchy.
*/
for (TABLE_LIST *tl= table_list; tl; tl= tl->next_local)
{
bool updated= false;
if (multi_update_check_table_access(thd, tl, tables_for_update, true,
&updated))
DBUG_RETURN(true);
}
// Check privileges for columns that are updated
{ // Opening scope for the RAII object
Item *item;
List_iterator_fast<Item> orig_it(original_update_fields);
Mark_field mf(MARK_COLUMNS_WRITE);
Column_privilege_tracker priv_tracker(thd, UPDATE_ACL);
while ((item= orig_it++))
{
if (item->walk(&Item::check_column_privileges, Item::WALK_PREFIX,
(uchar *)thd))
DBUG_RETURN(true);
item->walk(&Item::mark_field_in_map, Item::WALK_POSTFIX, (uchar *)&mf);
}
} // Closing scope for the RAII object
if (unsafe_key_update(select->leaf_tables, tables_for_update))
DBUG_RETURN(true);
/*
When using a multi-table UPDATE command as a prepared statement,
1) We must validate values (the right argument 'expr' of 'SET col1=expr')
during PREPARE, so that:
- bad columns are reported by PREPARE
- cached_table is set for fields before query transformations (semijoin,
view merging...) are done and make resolution more difficult.
2) This validation is done by Query_result_update::prepare() but it is
not called by PREPARE.
3) So we do it below.
@todo Remove this code duplication as part of WL#6570
*/
if (thd->stmt_arena->is_stmt_prepare())
{
if (setup_fields(thd, Ref_ptr_array(), update_value_list, SELECT_ACL,
NULL, false, false))
DBUG_RETURN(true);
/*
Check that table being updated is not being used in a subquery, but
skip all tables of the UPDATE query block itself
*/
select->exclude_from_table_unique_test= true;
for (TABLE_LIST *tr= select->leaf_tables; tr; tr= tr->next_leaf)
{
if (tr->lock_type != TL_READ &&
tr->lock_type != TL_READ_NO_INSERT)
{
TABLE_LIST *duplicate= unique_table(thd, tr, select->leaf_tables, 0);
if (duplicate != NULL)
{
update_non_unique_table_error(select->leaf_tables, "UPDATE",
duplicate);
DBUG_RETURN(true);
}
}
}
}
/* check single table update for view compound from several tables */
for (TABLE_LIST *tl= table_list; tl; tl= tl->next_local)
{
if (tl->is_merged())
{
assert(tl->is_view_or_derived());
TABLE_LIST *for_update= NULL;
if (tl->check_single_table(&for_update, tables_for_update))
{
my_error(ER_VIEW_MULTIUPDATE, MYF(0),
tl->view_db.str, tl->view_name.str);
DBUG_RETURN(true);
}
}
}
// Downgrade desired privileges for updated tables to SELECT
for (TABLE_LIST *tl= table_list; tl; tl= tl->next_local)
{
if (tl->updating)
tl->set_want_privilege(SELECT_ACL);
}
/* @todo: downgrade the metadata locks here. */
/*
Syntax rule for multi-table update prevents these constructs.
But they are possible for single-table UPDATE against multi-table view.
*/
if (select->order_list.elements)
{
my_error(ER_WRONG_USAGE, MYF(0), "UPDATE", "ORDER BY");
DBUG_RETURN(true);
}
if (select->select_limit)
{
my_error(ER_WRONG_USAGE, MYF(0), "UPDATE", "LIMIT");
DBUG_RETURN(true);
}
DBUG_RETURN(false);
}
/*
Setup multi-update handling and call SELECT to do the join
*/
bool mysql_multi_update(THD *thd,
List<Item> *fields,
List<Item> *values,
enum enum_duplicates handle_duplicates,
SELECT_LEX *select_lex,
Query_result_update **result)
{
bool res;
DBUG_ENTER("mysql_multi_update");
if (!(*result= new Query_result_update(select_lex->get_table_list(),
select_lex->leaf_tables,
fields, values,
handle_duplicates)))
DBUG_RETURN(true); /* purecov: inspected */
assert(select_lex->having_cond() == NULL &&
!select_lex->order_list.elements &&
!select_lex->group_list.elements &&
!select_lex->select_limit);
res= handle_query(thd, thd->lex, *result,
SELECT_NO_JOIN_CACHE | SELECT_NO_UNLOCK |
OPTION_SETUP_TABLES_DONE,
OPTION_BUFFER_RESULT);
DBUG_PRINT("info",("res: %d report_error: %d",res, (int) thd->is_error()));
res|= thd->is_error();
if (unlikely(res))
{
/* If we had a another error reported earlier then this will be ignored */
(*result)->send_error(ER_UNKNOWN_ERROR, ER(ER_UNKNOWN_ERROR));
(*result)->abort_result_set();
}
DBUG_RETURN(res);
}
Query_result_update::Query_result_update(TABLE_LIST *table_list,
TABLE_LIST *leaves_list,
List<Item> *field_list,
List<Item> *value_list,
enum enum_duplicates handle_duplicates_arg)
:all_tables(table_list), leaves(leaves_list), update_tables(0),
tmp_tables(0), updated(0), found(0), fields(field_list),
values(value_list), table_count(0), copy_field(0),
handle_duplicates(handle_duplicates_arg), do_update(1), trans_safe(1),
transactional_tables(0), error_handled(0), update_operations(NULL)
{}
/*
Connect fields with tables and create list of tables that are updated
*/
int Query_result_update::prepare(List<Item> ¬_used_values,
SELECT_LEX_UNIT *lex_unit)
{
SQL_I_List<TABLE_LIST> update;
List_iterator_fast<Item> field_it(*fields);
List_iterator_fast<Item> value_it(*values);
DBUG_ENTER("Query_result_update::prepare");
SELECT_LEX *const select= lex_unit->first_select();
thd->count_cuted_fields= CHECK_FIELD_WARN;
thd->cuted_fields=0L;
THD_STAGE_INFO(thd, stage_updating_main_table);
const table_map tables_to_update= get_table_map(fields);
if (!tables_to_update)
{
my_message(ER_NO_TABLES_USED, ER(ER_NO_TABLES_USED), MYF(0));
DBUG_RETURN(1);
}
/*
We gather the set of columns read during evaluation of SET expression in
TABLE::tmp_set by pointing TABLE::read_set to it and then restore it after
setup_fields().
*/
for (TABLE_LIST *tr= leaves; tr; tr= tr->next_leaf)
{
if (tables_to_update & tr->map())
{
TABLE *const table= tr->table;
assert(table->read_set == &table->def_read_set);
table->read_set= &table->tmp_set;
bitmap_clear_all(table->read_set);
}
// Resolving may be needed for subsequent executions
if (tr->check_option && !tr->check_option->fixed &&
tr->check_option->fix_fields(thd, NULL))
DBUG_RETURN(1); /* purecov: inspected */
}
/*
We have to check values after setup_tables to get covering_keys right in
reference tables
*/
int error= setup_fields(thd, Ref_ptr_array(), *values, SELECT_ACL, NULL,
false, false);
for (TABLE_LIST *tr= leaves; tr; tr= tr->next_leaf)
{
if (tables_to_update & tr->map())
{
TABLE *const table= tr->table;
table->read_set= &table->def_read_set;
bitmap_union(table->read_set, &table->tmp_set);
bitmap_clear_all(&table->tmp_set);
}
}
if (error)
DBUG_RETURN(1);
/*
Check that table being updated is not being used in a subquery, but
skip all tables of the UPDATE query block itself
*/
select->exclude_from_table_unique_test= true;
for (TABLE_LIST *tr= select->leaf_tables; tr; tr= tr->next_leaf)
{
if (tr->lock_type != TL_READ &&
tr->lock_type != TL_READ_NO_INSERT)
{
TABLE_LIST *duplicate= unique_table(thd, tr, all_tables, 0);
if (duplicate != NULL)
{
update_non_unique_table_error(all_tables, "UPDATE", duplicate);
DBUG_RETURN(true);
}
}
}
/*
Set exclude_from_table_unique_test value back to FALSE. It is needed for
further check whether to use record cache.
*/
select->exclude_from_table_unique_test= false;
/*
Save tables beeing updated in update_tables
update_table->shared is position for table
Don't use key read on tables that are updated
*/
update.empty();
uint leaf_table_count= 0;
for (TABLE_LIST *tr= leaves; tr; tr= tr->next_leaf)
{
/* TODO: add support of view of join support */
leaf_table_count++;
if (tables_to_update & tr->map())
{
TABLE_LIST *dup= (TABLE_LIST*) thd->memdup(tr, sizeof(*dup));
if (dup == NULL)
DBUG_RETURN(1);
TABLE *const table= tr->table;
update.link_in_list(dup, &dup->next_local);
tr->shared= dup->shared= table_count++;
table->no_keyread=1;
table->covering_keys.clear_all();
table->pos_in_table_list= dup;
if (table->triggers &&
table->triggers->has_triggers(TRG_EVENT_UPDATE,
TRG_ACTION_AFTER))
{
/*
The table has AFTER UPDATE triggers that might access to subject
table and therefore might need update to be done immediately.
So we turn-off the batching.
*/
(void) table->file->extra(HA_EXTRA_UPDATE_CANNOT_BATCH);
}
}
}
table_count= update.elements;
update_tables= update.first;
tmp_tables = (TABLE**) thd->mem_calloc(sizeof(TABLE *) * table_count);
tmp_table_param= new (thd->mem_root) Temp_table_param[table_count];
fields_for_table= (List_item **) thd->alloc(sizeof(List_item *) *
table_count);
values_for_table= (List_item **) thd->alloc(sizeof(List_item *) *
table_count);
assert(update_operations == NULL);
update_operations= (COPY_INFO**) thd->mem_calloc(sizeof(COPY_INFO*) *
table_count);
if (thd->is_error())
DBUG_RETURN(1);
for (uint i= 0; i < table_count; i++)
{
fields_for_table[i]= new List_item;
values_for_table[i]= new List_item;
}
if (thd->is_error())
DBUG_RETURN(1);
/* Split fields into fields_for_table[] and values_by_table[] */
Item *item;
while ((item= field_it++))
{
Item_field *const field= down_cast<Item_field *>(item);
Item *const value= value_it++;
uint offset= field->table_ref->shared;
fields_for_table[offset]->push_back(field);
values_for_table[offset]->push_back(value);
}
if (thd->is_fatal_error)
DBUG_RETURN(1);
/* Allocate copy fields */
uint max_fields= 0;
for (uint i= 0; i < table_count; i++)
set_if_bigger(max_fields, fields_for_table[i]->elements + leaf_table_count);
copy_field= new Copy_field[max_fields];
for (TABLE_LIST *ref= leaves; ref != NULL; ref= ref->next_leaf)
{
if (tables_to_update & ref->map())
{
const uint position= ref->shared;
List<Item> *cols= fields_for_table[position];
List<Item> *vals= values_for_table[position];
TABLE *const table= ref->table;
COPY_INFO *update=
new (thd->mem_root) COPY_INFO(COPY_INFO::UPDATE_OPERATION, cols, vals);
if (update == NULL ||
update->add_function_default_columns(table, table->write_set))
DBUG_RETURN(1);
update_operations[position]= update;
if ((table->file->ha_table_flags() & HA_PARTIAL_COLUMN_READ) != 0 &&
update->function_defaults_apply(table))
{
/*
A column is to be set to its ON UPDATE function default only if
other columns of the row are changing. To know this, we must be able
to compare the "before" and "after" value of those columns. Thus, we
must read those columns:
*/
bitmap_union(table->read_set, table->write_set);
}
/* All needed columns must be marked before prune_partitions(). */
if (table->triggers && table->triggers->mark_fields(TRG_EVENT_UPDATE))
DBUG_RETURN(true);
}
}
DBUG_RETURN(thd->is_fatal_error != 0);
}
/*
Check if table is safe to update on fly
SYNOPSIS
safe_update_on_fly()
thd Thread handler
join_tab How table is used in join
all_tables List of tables
NOTES
We can update the first table in join on the fly if we know that
a row in this table will never be read twice. This is true under
the following conditions:
- No column is both written to and read in SET expressions.
- We are doing a table scan and the data is in a separate file (MyISAM) or
if we don't update a clustered key.
- We are doing a range scan and we don't update the scan key or
the primary key for a clustered table handler.
- Table is not joined to itself.
This function gets information about fields to be updated from
the TABLE::write_set bitmap.
WARNING
This code is a bit dependent of how make_join_readinfo() works.
The field table->tmp_set is used for keeping track of which fields are
read during evaluation of the SET expression.
See Query_result_update::prepare.
RETURN
0 Not safe to update
1 Safe to update
*/
static bool safe_update_on_fly(THD *thd, JOIN_TAB *join_tab,
TABLE_LIST *table_ref, TABLE_LIST *all_tables)
{
TABLE *table= join_tab->table();
if (unique_table(thd, table_ref, all_tables, 0))
return 0;
switch (join_tab->type()) {
case JT_SYSTEM:
case JT_CONST:
case JT_EQ_REF:
return TRUE; // At most one matching row
case JT_REF:
case JT_REF_OR_NULL:
return !is_key_used(table, join_tab->ref().key, table->write_set);
case JT_ALL:
if (bitmap_is_overlapping(&table->tmp_set, table->write_set))
return FALSE;
/* If range search on index */
if (join_tab->quick())
return !join_tab->quick()->is_keys_used(table->write_set);
/* If scanning in clustered key */
if ((table->file->ha_table_flags() & HA_PRIMARY_KEY_IN_READ_INDEX) &&
table->s->primary_key < MAX_KEY)
return !is_key_used(table, table->s->primary_key, table->write_set);
return TRUE;
default:
break; // Avoid compler warning
}
return FALSE;
}
/*
Initialize table for multi table
IMPLEMENTATION
- Update first table in join on the fly, if possible
- Create temporary tables to store changed values for all other tables
that are updated (and main_table if the above doesn't hold).
*/
bool Query_result_update::initialize_tables(JOIN *join)
{
TABLE_LIST *table_ref;
DBUG_ENTER("initialize_tables");
ASSERT_BEST_REF_IN_JOIN_ORDER(join);
if ((thd->variables.option_bits & OPTION_SAFE_UPDATES) &&
error_if_full_join(join))
DBUG_RETURN(true);
main_table= join->best_ref[0]->table();
table_to_update= 0;
/* Any update has at least one pair (field, value) */
assert(fields->elements);
/*
Only one table may be modified by UPDATE of an updatable view.
For an updatable view first_table_for_update indicates this
table.
For a regular multi-update it refers to some updated table.
*/
TABLE_LIST *first_table_for_update= ((Item_field *)fields->head())->table_ref;
/* Create a temporary table for keys to all tables, except main table */
for (table_ref= update_tables; table_ref; table_ref= table_ref->next_local)
{
TABLE *table=table_ref->table;
uint cnt= table_ref->shared;
List<Item> temp_fields;
ORDER *group = NULL;
Temp_table_param *tmp_param;
if (table->vfield &&
validate_gc_assignment(thd, fields, values, table))
DBUG_RETURN(0);
if (thd->lex->is_ignore())
table->file->extra(HA_EXTRA_IGNORE_DUP_KEY);
if (table == main_table) // First table in join
{
/*
If there are at least two tables to update, t1 and t2, t1 being
before t2 in the plan, we need to collect all fields of t1 which
influence the selection of rows from t2. If those fields are also
updated, it will not be possible to update t1 on-the-fly.
Due to how the nested loop join algorithm works, when collecting
we can ignore the condition attached to t1 - a row of t1 is read
only one time.
*/
if (update_tables->next_local)
{
for (uint i= 1; i < join->tables; ++i)
{
JOIN_TAB *tab= join->best_ref[i];
if (tab->condition())
tab->condition()->walk(&Item::add_field_to_set_processor,
Item::enum_walk(Item::WALK_POSTFIX | Item::WALK_SUBQUERY),
reinterpret_cast<uchar *>(main_table));
/*
On top of checking conditions, we need to check conditions
referenced by index lookup on the following tables. They implement
conditions too, but their corresponding search conditions might
have been optimized away. The second table is an exception: even if
rows are read from it using index lookup which references a column
of main_table, the implementation of ref access will see the
before-update value;
consider this flow of a nested loop join:
read a row from main_table and:
- init ref access (cp_buffer_from_ref() in join_read_always_key()):
copy referenced value from main_table into 2nd table's ref buffer
- look up a first row in 2nd table (join_read_always_key)
- if it joins, update row of main_table on the fly
- look up a second row in 2nd table (join_read_next_same).
Because cp_buffer_from_ref() is not called again, the before-update
value of the row of main_table is still in the 2nd table's ref
buffer. So the lookup is not influenced by the just-done update of
main_table.
*/
if (tab > join->join_tab + 1)
{
for (uint i= 0; i < tab->ref().key_parts; i++)
{
Item *ref_item= tab->ref().items[i];
if ((table_ref->map() & ref_item->used_tables()) != 0)
ref_item->walk(&Item::add_field_to_set_processor,
Item::enum_walk(Item::WALK_POSTFIX | Item::WALK_SUBQUERY),
reinterpret_cast<uchar *>(main_table));
}
}
}
}
if (safe_update_on_fly(thd, join->best_ref[0], table_ref, all_tables))
{
table->mark_columns_needed_for_update(true/*mark_binlog_columns=true*/);
table_to_update= table; // Update table on the fly
continue;
}
}
table->mark_columns_needed_for_update(true/*mark_binlog_columns=true*/);
/*
enable uncacheable flag if we update a view with check option
and check option has a subselect, otherwise, the check option
can be evaluated after the subselect was freed as independent
(See full_local in JOIN::join_free()).
*/
if (table_ref->check_option && !join->select_lex->uncacheable)
{
SELECT_LEX_UNIT *tmp_unit;
SELECT_LEX *sl;
for (tmp_unit= join->select_lex->first_inner_unit();
tmp_unit;
tmp_unit= tmp_unit->next_unit())
{
for (sl= tmp_unit->first_select(); sl; sl= sl->next_select())
{
if (sl->master_unit()->item)
{
join->select_lex->uncacheable|= UNCACHEABLE_CHECKOPTION;
goto loop_end;
}
}
}
}
loop_end:
if (table_ref->table == first_table_for_update->table &&
table_ref->check_option)
{
table_map unupdated_tables= table_ref->check_option->used_tables() &
~first_table_for_update->map();
for (TABLE_LIST *tbl_ref =leaves;
unupdated_tables && tbl_ref;
tbl_ref= tbl_ref->next_leaf)
{
if (unupdated_tables & tbl_ref->map())
unupdated_tables&= ~tbl_ref->map();
else
continue;
if (unupdated_check_opt_tables.push_back(tbl_ref->table))
DBUG_RETURN(1);
}
}
tmp_param= tmp_table_param+cnt;
/*
Create a temporary table to store all fields that are changed for this
table. The first field in the temporary table is a pointer to the
original row so that we can find and update it. For the updatable
VIEW a few following fields are rowids of tables used in the CHECK
OPTION condition.
*/
List_iterator_fast<TABLE> tbl_it(unupdated_check_opt_tables);
TABLE *tbl= table;
do
{
/*
Signal each table (including tables referenced by WITH CHECK OPTION
clause) for which we will store row position in the temporary table
that we need a position to be read first.
*/
tbl->prepare_for_position();
/*
A tmp table is moved to InnoDB if it doesn't fit in memory,
and InnoDB does not support fixed length string fields bigger
than 1024 bytes, so use a variable length string field.
*/
Field_varstring *field = new Field_varstring(
tbl->file->ref_length, false, tbl->alias, tbl->s, &my_charset_bin);
if (!field)
DBUG_RETURN(1);
field->init(tbl);
/*
The field will be converted to varstring when creating tmp table if
table to be updated was created by mysql 4.1. Deny this.
*/
Item_field *ifield= new Item_field((Field *) field);
if (!ifield)
DBUG_RETURN(1);
ifield->maybe_null= 0;
if (temp_fields.push_back(ifield))
DBUG_RETURN(1);
} while ((tbl= tbl_it++));
temp_fields.concat(fields_for_table[cnt]);
/* Make an unique key over the first field to avoid duplicated updates */
group = new ORDER;
memset(group, 0, sizeof(*group));
group->direction = ORDER::ORDER_ASC;
group->item = temp_fields.head_ref();
tmp_param->quick_group=1;
tmp_param->field_count=temp_fields.elements;
tmp_param->group_parts=1;
tmp_param->group_length= table->file->ref_length;
/* small table, ignore SQL_BIG_TABLES */
my_bool save_big_tables= thd->variables.big_tables;
thd->variables.big_tables= FALSE;
tmp_tables[cnt]=create_tmp_table(thd, tmp_param, temp_fields,
group, 0, 0,
TMP_TABLE_ALL_COLUMNS, HA_POS_ERROR, "");
thd->variables.big_tables= save_big_tables;
if (!tmp_tables[cnt])
DBUG_RETURN(1);
/*
Pass a table triggers pointer (Table_trigger_dispatcher *) from
the original table to the new temporary table. This pointer will be used
inside the method Query_result_update::send_data() to determine temporary
nullability flag for the temporary table's fields. It will be done before
calling fill_record() to assign values to the temporary table's fields.
*/
tmp_tables[cnt]->triggers= table->triggers;
tmp_tables[cnt]->file->extra(HA_EXTRA_WRITE_CACHE);
tmp_tables[cnt]->file->ha_index_init(0, false /*sorted*/);
}
DBUG_RETURN(0);
}
Query_result_update::~Query_result_update()
{
TABLE_LIST *table;
for (table= update_tables ; table; table= table->next_local)
{
table->table->no_cache= 0;
if (thd->lex->is_ignore())
table->table->file->extra(HA_EXTRA_NO_IGNORE_DUP_KEY);
}
if (tmp_tables)
{
for (uint cnt = 0; cnt < table_count; cnt++)
{
if (tmp_tables[cnt])
{
tmp_tables[cnt]->file->ha_index_or_rnd_end();
delete tmp_tables[cnt]->group;
free_tmp_table(thd, tmp_tables[cnt]);
tmp_table_param[cnt].cleanup();
}
}
}
if (copy_field)
delete [] copy_field;
thd->count_cuted_fields= CHECK_FIELD_IGNORE; // Restore this setting
assert(trans_safe || !updated ||
thd->get_transaction()->cannot_safely_rollback(
Transaction_ctx::STMT));
if (update_operations != NULL)
for (uint i= 0; i < table_count; i++)
delete update_operations[i];
}
bool Query_result_update::send_data(List<Item> ¬_used_values)
{
TABLE_LIST *cur_table;
DBUG_ENTER("Query_result_update::send_data");
for (cur_table= update_tables; cur_table; cur_table= cur_table->next_local)
{
TABLE *table= cur_table->table;
uint offset= cur_table->shared;
/*
Check if we are using outer join and we didn't find the row
or if we have already updated this row in the previous call to this
function.
The same row may be presented here several times in a join of type
UPDATE t1 FROM t1,t2 SET t1.a=t2.a
In this case we will do the update for the first found row combination.
The join algorithm guarantees that we will not find the a row in
t1 several times.
*/
if (table->status & (STATUS_NULL_ROW | STATUS_UPDATED))
continue;
if (table == table_to_update)
{
table->status|= STATUS_UPDATED;
store_record(table,record[1]);
if (fill_record_n_invoke_before_triggers(thd, update_operations[offset],
*fields_for_table[offset],
*values_for_table[offset],
table,
TRG_EVENT_UPDATE, 0))
DBUG_RETURN(1);
/*
Reset the table->auto_increment_field_not_null as it is valid for
only one row.
*/
table->auto_increment_field_not_null= FALSE;
found++;
int error= 0;
if (!records_are_comparable(table) || compare_records(table))
{
update_operations[offset]->set_function_defaults(table);
if ((error= cur_table->view_check_option(thd)) !=
VIEW_CHECK_OK)
{
found--;
if (error == VIEW_CHECK_SKIP)
continue;
else if (error == VIEW_CHECK_ERROR)
DBUG_RETURN(1);
}
if (!updated++)
{
/*
Inform the main table that we are going to update the table even
while we may be scanning it. This will flush the read cache
if it's used.
*/
main_table->file->extra(HA_EXTRA_PREPARE_FOR_UPDATE);
}
if ((error=table->file->ha_update_row(table->record[1],
table->record[0])) &&
error != HA_ERR_RECORD_IS_THE_SAME)
{
updated--;
myf error_flags= MYF(0);
if (table->file->is_fatal_error(error))
error_flags|= ME_FATALERROR;
table->file->print_error(error, error_flags);
/* Errors could be downgraded to warning by IGNORE */
if (thd->is_error())
DBUG_RETURN(1);
}
else
{
if (error == HA_ERR_RECORD_IS_THE_SAME)
{
error= 0;
updated--;
}
/* non-transactional or transactional table got modified */
/* either Query_result_update class' flag is raised in its branch */
if (table->file->has_transactions())
transactional_tables= TRUE;
else
{
trans_safe= FALSE;
thd->get_transaction()->mark_modified_non_trans_table(
Transaction_ctx::STMT);
}
}
}
if (!error && table->triggers &&
table->triggers->process_triggers(thd, TRG_EVENT_UPDATE,
TRG_ACTION_AFTER, TRUE))
DBUG_RETURN(1);
}
else
{
int error;
TABLE *tmp_table= tmp_tables[offset];
/*
For updatable VIEW store rowid of the updated table and
rowids of tables used in the CHECK OPTION condition.
*/
uint field_num= 0;
List_iterator_fast<TABLE> tbl_it(unupdated_check_opt_tables);
TABLE *tbl= table;
do
{
tbl->file->position(tbl->record[0]);
tmp_table->visible_field_ptr()[field_num]->store(
reinterpret_cast<const char *>(tbl->file->ref),
tbl->file->ref_length, &my_charset_bin);
/*
For outer joins a rowid field may have no NOT_NULL_FLAG,
so we have to reset NULL bit for this field.
(set_notnull() resets NULL bit only if available).
*/
tmp_table->visible_field_ptr()[field_num]->set_notnull();
field_num++;
} while ((tbl= tbl_it++));
/*
If there are triggers in an original table the temporary table based on
then enable temporary nullability for temporary table's fields.
*/
if (tmp_table->triggers)
{
for (Field** modified_fields= tmp_table->visible_field_ptr() + 1 +
unupdated_check_opt_tables.elements;
*modified_fields; ++modified_fields)
{
(*modified_fields)->set_tmp_nullable();
}
}
/* Store regular updated fields in the row. */
fill_record(thd, tmp_table,
tmp_table->visible_field_ptr() +
1 + unupdated_check_opt_tables.elements,
*values_for_table[offset], NULL, NULL);
// check if a record exists with the same hash value
if (!check_unique_constraint(tmp_table))
DBUG_RETURN(0); // skip adding duplicate record to the temp table
/* Write row, ignoring duplicated updates to a row */
error= tmp_table->file->ha_write_row(tmp_table->record[0]);
if (error != HA_ERR_FOUND_DUPP_KEY && error != HA_ERR_FOUND_DUPP_UNIQUE)
{
if (error &&
(create_ondisk_from_heap(thd, tmp_table,
tmp_table_param[offset].start_recinfo,
&tmp_table_param[offset].recinfo,
error, TRUE, NULL) ||
tmp_table->file->ha_index_init(0, false /*sorted*/)))
{
do_update= 0;
DBUG_RETURN(1); // Not a table_is_full error
}
found++;
}
}
}
DBUG_RETURN(0);
}
void Query_result_update::send_error(uint errcode,const char *err)
{
/* First send error what ever it is ... */
my_error(errcode, MYF(0), err);
}
static void invalidate_update_tables(THD *thd, TABLE_LIST *update_tables)
{
for (TABLE_LIST *tl= update_tables; tl != NULL; tl= tl->next_local)
{
query_cache.invalidate_single(thd, tl->updatable_base_table(), 1);
}
}
void Query_result_update::abort_result_set()
{
/* the error was handled or nothing deleted and no side effects return */
if (error_handled ||
(!thd->get_transaction()->cannot_safely_rollback(
Transaction_ctx::STMT) && !updated))
return;
/* Something already updated so we have to invalidate cache */
if (updated)
invalidate_update_tables(thd, update_tables);
/*
If all tables that has been updated are trans safe then just do rollback.
If not attempt to do remaining updates.
*/
if (! trans_safe)
{
assert(thd->get_transaction()->cannot_safely_rollback(
Transaction_ctx::STMT));
if (do_update && table_count > 1)
{
/* Add warning here */
/*
todo/fixme: do_update() is never called with the arg 1.
should it change the signature to become argless?
*/
(void) do_updates();
}
}
if (thd->get_transaction()->cannot_safely_rollback(Transaction_ctx::STMT))
{
/*
The query has to binlog because there's a modified non-transactional table
either from the query's list or via a stored routine: bug#13270,23333
*/
if (mysql_bin_log.is_open())
{
/*
THD::killed status might not have been set ON at time of an error
got caught and if happens later the killed error is written
into repl event.
*/
int errcode= query_error_code(thd, thd->killed == THD::NOT_KILLED);
/* the error of binary logging is ignored */
(void)thd->binlog_query(THD::ROW_QUERY_TYPE,
thd->query().str, thd->query().length,
transactional_tables, false, false, errcode);
}
}
assert(trans_safe || !updated ||
thd->get_transaction()->cannot_safely_rollback(
Transaction_ctx::STMT));
}
int Query_result_update::do_updates()
{
TABLE_LIST *cur_table;
int local_error= 0;
ha_rows org_updated;
TABLE *table, *tmp_table;
List_iterator_fast<TABLE> check_opt_it(unupdated_check_opt_tables);
myf error_flags= MYF(0); /**< Flag for fatal errors */
DBUG_ENTER("Query_result_update::do_updates");
do_update= 0; // Don't retry this function
if (!found)
{
/*
If the binary log is on, we still need to check
if there are transactional tables involved. If
there are mark the transactional_tables flag correctly.
This flag determines whether the writes go into the
transactional or non transactional cache, even if they
do not change any table, they are still written into
the binary log when the format is STMT or MIXED.
*/
if(mysql_bin_log.is_open())
{
for (cur_table= update_tables; cur_table;
cur_table= cur_table->next_local)
{
table = cur_table->table;
transactional_tables= transactional_tables ||
table->file->has_transactions();
}
}
DBUG_RETURN(0);
}
for (cur_table= update_tables; cur_table; cur_table= cur_table->next_local)
{
uint offset= cur_table->shared;
table = cur_table->table;
/*
Always update the flag if - even if not updating the table,
when the binary log is ON. This will allow the right binlog
cache - stmt or trx cache - to be selected when logging
innefective statementst to the binary log (in STMT or MIXED
mode logging).
*/
if (mysql_bin_log.is_open())
transactional_tables= transactional_tables || table->file->has_transactions();
if (table == table_to_update)
continue; // Already updated
org_updated= updated;
tmp_table= tmp_tables[cur_table->shared];
tmp_table->file->ha_index_or_rnd_end();
tmp_table->file->extra(HA_EXTRA_CACHE); // Change to read cache
if ((local_error= table->file->ha_rnd_init(0)))
{
if (table->file->is_fatal_error(local_error))
error_flags|= ME_FATALERROR;
table->file->print_error(local_error, error_flags);
goto err;
}
table->file->extra(HA_EXTRA_NO_CACHE);
check_opt_it.rewind();
while(TABLE *tbl= check_opt_it++)
{
if (tbl->file->ha_rnd_init(1))
// No known handler error code present, print_error makes no sense
goto err;
tbl->file->extra(HA_EXTRA_CACHE);
}
/*
Setup copy functions to copy fields from temporary table
*/
List_iterator_fast<Item> field_it(*fields_for_table[offset]);
Field **field= tmp_table->visible_field_ptr() +
1 + unupdated_check_opt_tables.elements; // Skip row pointers
Copy_field *copy_field_ptr= copy_field, *copy_field_end;
for ( ; *field ; field++)
{
Item_field *item= (Item_field* ) field_it++;
(copy_field_ptr++)->set(item->field, *field, 0);
}
copy_field_end=copy_field_ptr;
if ((local_error = tmp_table->file->ha_rnd_init(1)))
{
if (table->file->is_fatal_error(local_error))
error_flags|= ME_FATALERROR;
table->file->print_error(local_error, error_flags);
goto err;
}
for (;;)
{
if (thd->killed && trans_safe)
// No known handler error code present, print_error makes no sense
goto err;
if ((local_error=tmp_table->file->ha_rnd_next(tmp_table->record[0])))
{
if (local_error == HA_ERR_END_OF_FILE)
break;
if (local_error == HA_ERR_RECORD_DELETED)
continue; // May happen on dup key
if (table->file->is_fatal_error(local_error))
error_flags|= ME_FATALERROR;
table->file->print_error(local_error, error_flags);
goto err;
}
/* call ha_rnd_pos() using rowids from temporary table */
check_opt_it.rewind();
TABLE *tbl= table;
uint field_num= 0;
do
{
/*
The row-id is after the "length bytes", and the storage
engine knows its length. Pass the pointer to the data after
the "length bytes" to ha_rnd_pos().
*/
uchar *data_ptr = NULL;
tmp_table->visible_field_ptr()[field_num]->get_ptr(&data_ptr);
if ((local_error = tbl->file->ha_rnd_pos(
tbl->record[0],
const_cast<uchar *>(data_ptr)))) {
if (table->file->is_fatal_error(local_error))
error_flags|= ME_FATALERROR;
table->file->print_error(local_error, error_flags);
goto err;
}
field_num++;
} while((tbl= check_opt_it++));
table->status|= STATUS_UPDATED;
store_record(table,record[1]);
/* Copy data from temporary table to current table */
for (copy_field_ptr=copy_field;
copy_field_ptr != copy_field_end;
copy_field_ptr++)
copy_field_ptr->invoke_do_copy(copy_field_ptr);
// The above didn't update generated columns
if (table->vfield &&
update_generated_write_fields(table->write_set, table))
goto err;
if (table->triggers)
{
bool rc= table->triggers->process_triggers(thd, TRG_EVENT_UPDATE,
TRG_ACTION_BEFORE, true);
// Trigger might have changed dependencies of generated columns
if (!rc && table->vfield &&
update_generated_write_fields(table->write_set, table))
goto err;
table->triggers->disable_fields_temporary_nullability();
if (rc || check_record(thd, table->field))
goto err;
}
if (!records_are_comparable(table) || compare_records(table))
{
update_operations[offset]->set_function_defaults(table);
int error;
if ((error= cur_table->view_check_option(thd)) !=
VIEW_CHECK_OK)
{
if (error == VIEW_CHECK_SKIP)
continue;
else if (error == VIEW_CHECK_ERROR)
// No known handler error code present, print_error makes no sense
goto err;
}
local_error= table->file->ha_update_row(table->record[1],
table->record[0]);
if (!local_error)
updated++;
else if (local_error == HA_ERR_RECORD_IS_THE_SAME)
local_error= 0;
else
{
if (table->file->is_fatal_error(local_error))
error_flags|= ME_FATALERROR;
table->file->print_error(local_error, error_flags);
/* Errors could be downgraded to warning by IGNORE */
if (thd->is_error())
goto err;
}
}
if (!local_error && table->triggers &&
table->triggers->process_triggers(thd, TRG_EVENT_UPDATE,
TRG_ACTION_AFTER, TRUE))
goto err;
}
if (updated != org_updated)
{
if (!table->file->has_transactions())
{
trans_safe= FALSE; // Can't do safe rollback
thd->get_transaction()->mark_modified_non_trans_table(
Transaction_ctx::STMT);
}
}
(void) table->file->ha_rnd_end();
(void) tmp_table->file->ha_rnd_end();
check_opt_it.rewind();
while (TABLE *tbl= check_opt_it++)
tbl->file->ha_rnd_end();
}
DBUG_RETURN(0);
err:
if (table->file->inited)
(void) table->file->ha_rnd_end();
if (tmp_table->file->inited)
(void) tmp_table->file->ha_rnd_end();
check_opt_it.rewind();
while (TABLE *tbl= check_opt_it++)
{
if (tbl->file->inited)
(void) tbl->file->ha_rnd_end();
}
if (updated != org_updated)
{
if (table->file->has_transactions())
transactional_tables= TRUE;
else
{
trans_safe= FALSE;
thd->get_transaction()->mark_modified_non_trans_table(
Transaction_ctx::STMT);
}
}
DBUG_RETURN(1);
}
/* out: 1 if error, 0 if success */
bool Query_result_update::send_eof()
{
char buff[STRING_BUFFER_USUAL_SIZE];
ulonglong id;
THD::killed_state killed_status= THD::NOT_KILLED;
DBUG_ENTER("Query_result_update::send_eof");
THD_STAGE_INFO(thd, stage_updating_reference_tables);
/*
Does updates for the last n - 1 tables, returns 0 if ok;
error takes into account killed status gained in do_updates()
*/
int local_error= thd->is_error();
if (!local_error)
local_error = (table_count) ? do_updates() : 0;
/*
if local_error is not set ON until after do_updates() then
later carried out killing should not affect binlogging.
*/
killed_status= (local_error == 0)? THD::NOT_KILLED : thd->killed;
THD_STAGE_INFO(thd, stage_end);
/* We must invalidate the query cache before binlog writing and
ha_autocommit_... */
if (updated)
invalidate_update_tables(thd, update_tables);
/*
Write the SQL statement to the binlog if we updated
rows and we succeeded or if we updated some non
transactional tables.
The query has to binlog because there's a modified non-transactional table
either from the query's list or via a stored routine: bug#13270,23333
*/
if (local_error == 0 ||
thd->get_transaction()->cannot_safely_rollback(Transaction_ctx::STMT))
{
if (mysql_bin_log.is_open())
{
int errcode= 0;
if (local_error == 0)
thd->clear_error();
else
errcode= query_error_code(thd, killed_status == THD::NOT_KILLED);
if (thd->binlog_query(THD::ROW_QUERY_TYPE,
thd->query().str, thd->query().length,
transactional_tables, FALSE, FALSE, errcode))
{
local_error= 1; // Rollback update
}
}
}
assert(trans_safe || !updated ||
thd->get_transaction()->cannot_safely_rollback(
Transaction_ctx::STMT));
if (local_error != 0)
error_handled= TRUE; // to force early leave from ::send_error()
if (local_error > 0) // if the above log write did not fail ...
{
/* Safety: If we haven't got an error before (can happen in do_updates) */
my_message(ER_UNKNOWN_ERROR, "An error occured in multi-table update",
MYF(0));
DBUG_RETURN(TRUE);
}
id= thd->arg_of_last_insert_id_function ?
thd->first_successful_insert_id_in_prev_stmt : 0;
my_snprintf(buff, sizeof(buff), ER(ER_UPDATE_INFO),
(long) found, (long) updated,
(long) thd->get_stmt_da()->current_statement_cond_count());
::my_ok(thd, thd->get_protocol()->has_client_capability(CLIENT_FOUND_ROWS) ?
found : updated, id, buff);
DBUG_RETURN(FALSE);
}
/**
Try to execute UPDATE as single-table UPDATE
If the UPDATE statement can be executed as a single-table UPDATE,
the do it. Otherwise defer its execution for the further
execute_multi_table_update() call outside this function and set
switch_to_multitable to "true".
@param thd Current THD.
@param [out] switch_to_multitable True if the UPDATE statement can't
be evaluated as single-table.
Note: undefined if the function
returns "true".
@return true on error
@return false otherwise.
*/
bool Sql_cmd_update::try_single_table_update(THD *thd,
bool *switch_to_multitable)
{
LEX *const lex= thd->lex;
SELECT_LEX *const select_lex= lex->select_lex;
SELECT_LEX_UNIT *const unit= lex->unit;
TABLE_LIST *const first_table= select_lex->get_table_list();
TABLE_LIST *const all_tables= first_table;
if (update_precheck(thd, all_tables))
return true;
/*
UPDATE IGNORE can be unsafe. We therefore use row based
logging if mixed or row based logging is available.
TODO: Check if the order of the output of the select statement is
deterministic. Waiting for BUG#42415
*/
if (lex->is_ignore())
lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_UPDATE_IGNORE);
assert(select_lex->offset_limit == 0);
unit->set_limit(select_lex);
MYSQL_UPDATE_START(const_cast<char*>(thd->query().str));
// Need to open to check for multi-update
if (open_tables_for_query(thd, all_tables, 0) ||
mysql_update_prepare_table(thd, select_lex) ||
run_before_dml_hook(thd))
return true;
if (!all_tables->is_multiple_tables())
{
/* Push ignore / strict error handler */
Ignore_error_handler ignore_handler;
Strict_error_handler strict_handler;
if (thd->lex->is_ignore())
thd->push_internal_handler(&ignore_handler);
else if (thd->is_strict_mode())
thd->push_internal_handler(&strict_handler);
ha_rows found= 0, updated= 0;
const bool res= mysql_update(thd, select_lex->item_list,
update_value_list,
unit->select_limit_cnt,
lex->duplicates,
&found, &updated);
/* Pop ignore / strict error handler */
if (thd->lex->is_ignore() || thd->is_strict_mode())
thd->pop_internal_handler();
MYSQL_UPDATE_DONE(res, found, updated);
if (res)
return true;
else
{
*switch_to_multitable= false;
return false;
}
}
else
{
assert(all_tables->is_view());
DBUG_PRINT("info", ("Switch to multi-update"));
if (!thd->in_sub_stmt)
thd->query_plan.set_query_plan(SQLCOM_UPDATE_MULTI, lex,
!thd->stmt_arena->is_conventional());
MYSQL_UPDATE_DONE(true, 0, 0);
*switch_to_multitable= true;
return false;
}
}
bool Sql_cmd_update::execute_multi_table_update(THD *thd)
{
bool res= false;
LEX *const lex= thd->lex;
SELECT_LEX *const select_lex= lex->select_lex;
TABLE_LIST *const first_table= select_lex->get_table_list();
TABLE_LIST *const all_tables= first_table;
#ifdef HAVE_REPLICATION
/* have table map for update for multi-update statement (BUG#37051) */
/*
Save the thd->table_map_for_update value as a result of the
Query_log_event::do_apply_event() function call --
the mysql_multi_update_prepare() function will reset it below.
*/
const bool have_table_map_for_update= thd->table_map_for_update;
#endif
res= mysql_multi_update_prepare(thd);
#ifdef HAVE_REPLICATION
/* Check slave filtering rules */
if (unlikely(thd->slave_thread && !have_table_map_for_update))
{
if (all_tables_not_ok(thd, all_tables))
{
if (res!= 0)
{
res= 0; /* don't care of prev failure */
thd->clear_error(); /* filters are of highest prior */
}
/* we warn the slave SQL thread */
my_error(ER_SLAVE_IGNORED_TABLE, MYF(0));
return res;
}
if (res)
return res;
}
else
{
#endif /* HAVE_REPLICATION */
if (res)
return res;
if (check_readonly(thd, false) &&
some_non_temp_table_to_be_updated(thd, all_tables))
{
err_readonly(thd);
return res;
}
#ifdef HAVE_REPLICATION
} /* unlikely */
#endif
{
/* Push ignore / strict error handler */
Ignore_error_handler ignore_handler;
Strict_error_handler strict_handler;
if (thd->lex->is_ignore())
thd->push_internal_handler(&ignore_handler);
else if (thd->is_strict_mode())
thd->push_internal_handler(&strict_handler);
Query_result_update *result_obj;
MYSQL_MULTI_UPDATE_START(const_cast<char*>(thd->query().str));
res= mysql_multi_update(thd,
&select_lex->item_list,
&update_value_list,
lex->duplicates,
select_lex,
&result_obj);
/* Pop ignore / strict error handler */
if (thd->lex->is_ignore() || thd->is_strict_mode())
thd->pop_internal_handler();
if (result_obj)
{
MYSQL_MULTI_UPDATE_DONE(res, result_obj->num_found(),
result_obj->num_updated());
res= FALSE; /* Ignore errors here */
delete result_obj;
}
else
{
MYSQL_MULTI_UPDATE_DONE(1, 0, 0);
}
}
return res;
}
bool Sql_cmd_update::execute(THD *thd)
{
if (thd->lex->sql_command == SQLCOM_UPDATE_MULTI)
{
return multi_update_precheck(thd, thd->lex->select_lex->get_table_list()) ||
execute_multi_table_update(thd);
}
bool switch_to_multitable;
if (try_single_table_update(thd, &switch_to_multitable))
return true;
if (switch_to_multitable)
{
sql_command= SQLCOM_UPDATE_MULTI;
return execute_multi_table_update(thd);
}
return false;
}
bool Sql_cmd_update::prepared_statement_test(THD *thd)
{
assert(thd->lex->query_tables == thd->lex->select_lex->get_table_list());
if (thd->lex->sql_command == SQLCOM_UPDATE)
{
int res= mysql_test_update(thd);
/* mysql_test_update returns 2 if we need to switch to multi-update */
if (res == 2)
return select_like_stmt_cmd_test(thd, this, OPTION_SETUP_TABLES_DONE);
else
return MY_TEST(res);
}
else
{
return multi_update_precheck(thd, thd->lex->query_tables) ||
select_like_stmt_cmd_test(thd, this, OPTION_SETUP_TABLES_DONE);
}
}