A heuristic in best_access_path says that if for an index
ref access involved key parts which are greater than equal to that
for range access, then range access should not be considered.
The assumption made by this heuristic does not hold when
the range optimizer opted to use the group-by min-max optimization.
So the fix here would be to not consider the heuristic if
the range optimizer picked the usage of group-by min-max
optimization.
Due to a premature cleanup of the unit that specified a recursive CTE
used in the second operand of union the server fell into an infinite
loop in the reported test case. In other cases this premature cleanup
could cause other problems.
The bug is the result of a not quite correct fix for MDEV-17024. The
unit that specifies a recursive CTE has to be cleaned only after the
cleanup of the last external reference to this CTE. It means that
cleanups of the unit triggered not by the cleanup of a external
reference to the CTE must be blocked.
Usage of local table chains in selects to get external references to
recursive CTEs was not correct either because of possible merges of
some selects.
Also fixed a minor bug in st_select_lex::set_explain_type() that caused
typing 'RECURSIVE UNION' instead of 'UNION' in EXPLAIN output for external
references to a recursive CTE.
This follows up commit
commit 94a520ddbe and
commit 7c5519c12d.
After these changes, the default test suites on a
cmake -DWITH_UBSAN=ON build no longer fail due to passing
null pointers as parameters that are declared to never be null,
but plenty of other runtime errors remain.
Reimplement MDEV-14275 Improving memory utilization for information schema
Postpone temp table instantiation until after setup_fields().
Replace all unused (not marked in read_set) columns in an I_S table
with CHAR(0). This can drastically reduce the footprint of a MEMORY
table (a TABLE_CATALOG alone is 1538 bytes per row).
This does not change the engine. If the table was decided to be Aria
(because of, say, blobs) then after optimization it'll stay Aria
even if all blobs were removed.
Note 1: when transforming table structure, share->blob_fields is
preserved, otherwise Aria might switch from DYNAMIC to STATIC row format
and expect a special field for a deleted mark, which create_tmp_tabe
didn't provide.
Note 2: optimizer was doing handler::info() (to know the number of rows)
before the temp table is populated. That didn't make much sense. Now
it's done before the table is even instantiated. Preserve the old
behavior and report 0 rows.
This reverts e2664ee836 and a8458a2345
PARTITION clause in SELECT means query is non-versioned (see
WITH_PARTITION_STORAGE_ENGINE in vers_setup_conds()).
vers_setup_conds() expands such query to SYSTEM_TIME_ALL which is then
added to VIEW specification. When VIEW is queried both clauses
PARTITION and FOR SYSTEM_TIME ALL lead to ER_VERS_QUERY_IN_PARTITION
(same place WITH_PARTITION_STORAGE_ENGINE).
Fix removes FOR SYSTEM_TIME ALL from VIEW by accessing original
SYSTEM_TIME clause: the one specified in parser. As a side-effect
EXPLAIN SELECT displays SYSTEM_TIME specified in SELECT which is
user-friendly.
For join to work correctly versioning condition must be added to table
on_expr. Without that JOIN_CACHE gets expression (1)
trigcond(xtitle.row_end = TIMESTAMP'2038-01-19 06:14:07.999999') and
trigcond(xtitle.elementId = x.`id` and xtitle.pkey = 'title')
instead of (2)
trigcond(xtitle.elementId = x.`id` and xtitle.pkey = 'title')
for join_null_complements(). It is NULL-row of xtitle for
complementing the join and the above comparisons of course FALSE, but
trigcond (Item_func_trig_cond) makes them TRUE via its trig_var
property which is bound to some boolean properties of JOIN_TAB.
Expression (2) evaluated to TRUE because its trig_var is bound to
first_inner_tab->not_null_compl. The expression (1) does not evaluate
correctly because row_end comparison's trig_var is bound to
first_inner->found earlier. As a result JOIN_CACHE::check_match()
skipped the row for join_null_complements().
When we add versioning condition to table's on_expr the optimizer in
make_join_select() distributes conditions differently. tmp_cond
inherits on_expr value and in Good case it is full expression
xgender.elementId = x.`id` and xgender.pkey = 'gender' and
xgender.row_end = TIMESTAMP'2038-01-19 06:14:07.999999'
while in Bad case it is only
xgender.elementId = x.`id` and xgender.pkey = 'gender'.
Later in Good row_end condition is optimized out and we get one
trigcond in form of (2).
Diagnostics_area::set_error_status
Analysis: When strict mode is enabled, all warnings are converted to errors
including those which do not occur because of bad data.
Fix: Query should not be aborted when we have warning because limit to
examine rows was reached because it doesn't happen due to bad data.
So thd->abort_on_warning should be false.
The issue here was that the query was using ORDER BY LIMIT optimzation where
the access method was changed from EQ_REF access to an index scan (index that would
resolve the ORDER BY clause).
But the parameter READ_RECORD::unlock_row was not reset to rr_unlock_row, which is
used when the access method is not EQ_REF access.
Problem:
Queries like this showed performance degratation in 10.4 over 10.3:
SELECT temporal_literal FROM t1;
SELECT temporal_literal + 1 FROM t1;
SELECT COUNT(*) FROM t1 WHERE temporal_column = temporal_literal;
SELECT COUNT(*) FROM t1 WHERE temporal_column = string_literal;
Fix:
Replacing the universal member "MYSQL_TIME cached_time" in
Item_temporal_literal to data type specific containers:
- Date in Item_date_literal
- Time in Item_time_literal
- Datetime in Item_datetime_literal
This restores the performance, and make it even better in some cases.
See benchmark results in MDEV.
Also, this change makes futher separations of Date, Time, Datetime
from each other, which will make it possible not to derive them from
a too heavy (40 bytes) MYSQL_TIME, and replace them to smaller data
type specific containers.
The issue here is when records are read from the temporary file
(filesort result in this case) via a cache(rr_from_cache).
The cache is initialized with init_rr_cache.
For correlated subquery the cache allocation is happening at each execution
of the subquery but the deallocation happens only once and that was
when the query execution was done.
So generally for subqueries we do two types of cleanup
1) Full cleanup: we should free all resources of the query(like temp tables).
This is done generally when the query execution is complete or the subquery
re-execution is not needed (case with uncorrelated subquery)
2) Partial cleanup: Minor cleanup that is required if
the subquery needs recalculation. This is done for all the structures that
need to be allocated for each execution (example SORT_INFO for filesort
is allocated for each execution of the correlated subquery).
The fix here would be free the cache used by rr_from_cache in the partial
cleanup phase.
