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Kirill Smelkov
mariadb
Commits
2834bc1e
Commit
2834bc1e
authored
Jul 14, 2006
by
sergefp@pylon.mylan
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Merge mysql.com:/home/psergey/tmp_merge-2
into mysql.com:/home/psergey/mysql-5.1-merge-2
parents
436e7a2d
775ec4fb
Changes
3
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3 changed files
with
225 additions
and
4 deletions
+225
-4
mysql-test/r/range.result
mysql-test/r/range.result
+21
-0
mysql-test/t/range.test
mysql-test/t/range.test
+25
-0
sql/opt_range.cc
sql/opt_range.cc
+179
-4
No files found.
mysql-test/r/range.result
View file @
2834bc1e
...
@@ -644,6 +644,27 @@ SELECT count(*) FROM t1 WHERE CLIENT='000' AND (ARG1 != ' 2' OR ARG1 != ' 1');
...
@@ -644,6 +644,27 @@ SELECT count(*) FROM t1 WHERE CLIENT='000' AND (ARG1 != ' 2' OR ARG1 != ' 1');
count(*)
count(*)
4
4
drop table t1;
drop table t1;
create table t1 (a int);
insert into t1 values (0),(1),(2),(3),(4),(5),(6),(7),(8),(9);
CREATE TABLE t2 (
pk1 int(11) NOT NULL,
pk2 int(11) NOT NULL,
pk3 int(11) NOT NULL,
pk4 int(11) NOT NULL,
filler char(82),
PRIMARY KEY (pk1,pk2,pk3,pk4)
) DEFAULT CHARSET=latin1;
insert into t2 select 1, A.a+10*B.a, 432, 44, 'fillerZ' from t1 A, t1 B;
INSERT INTO t2 VALUES (2621, 2635, 0, 0,'filler'), (2621, 2635, 1, 0,'filler'),
(2621, 2635, 10, 0,'filler'), (2621, 2635, 11, 0,'filler'),
(2621, 2635, 14, 0,'filler'), (2621, 2635, 1000015, 0,'filler');
SELECT * FROM t2
WHERE ((((pk4 =0) AND (pk1 =2621) AND (pk2 =2635)))
OR ((pk4 =1) AND (((pk1 IN ( 7, 2, 1 ))) OR (pk1 =522)) AND ((pk2 IN ( 0, 2635))))
) AND (pk3 >=1000000);
pk1 pk2 pk3 pk4 filler
2621 2635 1000015 0 filler
drop table t1, t2;
CREATE TABLE t1 (
CREATE TABLE t1 (
id int(11) NOT NULL auto_increment,
id int(11) NOT NULL auto_increment,
status varchar(20),
status varchar(20),
...
...
mysql-test/t/range.test
View file @
2834bc1e
...
@@ -490,6 +490,31 @@ SELECT count(*) FROM t1 WHERE CLIENT='000' AND (ARG1 != ' 1' OR ARG1 != ' 2');
...
@@ -490,6 +490,31 @@ SELECT count(*) FROM t1 WHERE CLIENT='000' AND (ARG1 != ' 1' OR ARG1 != ' 2');
SELECT
count
(
*
)
FROM
t1
WHERE
CLIENT
=
'000'
AND
(
ARG1
!=
' 2'
OR
ARG1
!=
' 1'
);
SELECT
count
(
*
)
FROM
t1
WHERE
CLIENT
=
'000'
AND
(
ARG1
!=
' 2'
OR
ARG1
!=
' 1'
);
drop
table
t1
;
drop
table
t1
;
# BUG#16168: Wrong range optimizer results, "Use_count: Wrong count ..."
# warnings in server stderr.
create
table
t1
(
a
int
);
insert
into
t1
values
(
0
),(
1
),(
2
),(
3
),(
4
),(
5
),(
6
),(
7
),(
8
),(
9
);
CREATE
TABLE
t2
(
pk1
int
(
11
)
NOT
NULL
,
pk2
int
(
11
)
NOT
NULL
,
pk3
int
(
11
)
NOT
NULL
,
pk4
int
(
11
)
NOT
NULL
,
filler
char
(
82
),
PRIMARY
KEY
(
pk1
,
pk2
,
pk3
,
pk4
)
)
DEFAULT
CHARSET
=
latin1
;
insert
into
t2
select
1
,
A
.
a
+
10
*
B
.
a
,
432
,
44
,
'fillerZ'
from
t1
A
,
t1
B
;
INSERT
INTO
t2
VALUES
(
2621
,
2635
,
0
,
0
,
'filler'
),
(
2621
,
2635
,
1
,
0
,
'filler'
),
(
2621
,
2635
,
10
,
0
,
'filler'
),
(
2621
,
2635
,
11
,
0
,
'filler'
),
(
2621
,
2635
,
14
,
0
,
'filler'
),
(
2621
,
2635
,
1000015
,
0
,
'filler'
);
SELECT
*
FROM
t2
WHERE
((((
pk4
=
0
)
AND
(
pk1
=
2621
)
AND
(
pk2
=
2635
)))
OR
((
pk4
=
1
)
AND
(((
pk1
IN
(
7
,
2
,
1
)))
OR
(
pk1
=
522
))
AND
((
pk2
IN
(
0
,
2635
))))
)
AND
(
pk3
>=
1000000
);
drop
table
t1
,
t2
;
# End of 4.1 tests
# End of 4.1 tests
#
#
...
...
sql/opt_range.cc
View file @
2834bc1e
...
@@ -85,18 +85,119 @@ static int sel_cmp(Field *f,char *a,char *b,uint8 a_flag,uint8 b_flag);
...
@@ -85,18 +85,119 @@ static int sel_cmp(Field *f,char *a,char *b,uint8 a_flag,uint8 b_flag);
static
char
is_null_string
[
2
]
=
{
1
,
0
};
static
char
is_null_string
[
2
]
=
{
1
,
0
};
/*
A construction block of the SEL_ARG-graph.
The following description only covers graphs of SEL_ARG objects with
sel_arg->type==KEY_RANGE:
One SEL_ARG object represents an "elementary interval" in form
min_value <=? table.keypartX <=? max_value
The interval is a non-empty interval of any kind: with[out] minimum/maximum
bound, [half]open/closed, single-point interval, etc.
1. SEL_ARG GRAPH STRUCTURE
SEL_ARG objects are linked together in a graph. The meaning of the graph
is better demostrated by an example:
tree->keys[i]
|
| $ $
| part=1 $ part=2 $ part=3
| $ $
| +-------+ $ +-------+ $ +--------+
| | kp1<1 |--$-->| kp2=5 |--$-->| kp3=10 |
| +-------+ $ +-------+ $ +--------+
| | $ $ |
| | $ $ +--------+
| | $ $ | kp3=12 |
| | $ $ +--------+
| +-------+ $ $
\->| kp1=2 |--$--------------$-+
+-------+ $ $ | +--------+
| $ $ ==>| kp3=11 |
+-------+ $ $ | +--------+
| kp1=3 |--$--------------$-+ |
+-------+ $ $ +--------+
| $ $ | kp3=14 |
... $ $ +--------+
The entire graph is partitioned into "interval lists".
An interval list is a sequence of ordered disjoint intervals over the same
key part. SEL_ARG are linked via "next" and "prev" pointers. Additionally,
all intervals in the list form an RB-tree, linked via left/right/parent
pointers. The RB-tree root SEL_ARG object will be further called "root of the
interval list".
In the example pic, there are 4 interval lists:
"kp<1 OR kp1=2 OR kp1=3", "kp2=5", "kp3=10 OR kp3=12", "kp3=11 OR kp3=13".
The vertical lines represent SEL_ARG::next/prev pointers.
In an interval list, each member X may have SEL_ARG::next_key_part pointer
pointing to the root of another interval list Y. The pointed interval list
must cover a key part with greater number (i.e. Y->part > X->part).
In the example pic, the next_key_part pointers are represented by
horisontal lines.
2. SEL_ARG GRAPH SEMANTICS
It represents a condition in a special form (we don't have a name for it ATM)
The SEL_ARG::next/prev is "OR", and next_key_part is "AND".
For example, the picture represents the condition in form:
(kp1 < 1 AND kp2=5 AND (kp3=10 OR kp3=12)) OR
(kp1=2 AND (kp3=11 OR kp3=14)) OR
(kp1=3 AND (kp3=11 OR kp3=14))
3. SEL_ARG GRAPH USE
Use get_mm_tree() to construct SEL_ARG graph from WHERE condition.
Then walk the SEL_ARG graph and get a list of dijsoint ordered key
intervals (i.e. intervals in form
(constA1, .., const1_K) < (keypart1,.., keypartK) < (constB1, .., constB_K)
Those intervals can be used to access the index. The uses are in:
- check_quick_select() - Walk the SEL_ARG graph and find an estimate of
how many table records are contained within all
intervals.
- get_quick_select() - Walk the SEL_ARG, materialize the key intervals,
and create QUICK_RANGE_SELECT object that will
read records within these intervals.
*/
class
SEL_ARG
:
public
Sql_alloc
class
SEL_ARG
:
public
Sql_alloc
{
{
public:
public:
uint8
min_flag
,
max_flag
,
maybe_flag
;
uint8
min_flag
,
max_flag
,
maybe_flag
;
uint8
part
;
// Which key part
uint8
part
;
// Which key part
uint8
maybe_null
;
uint8
maybe_null
;
uint16
elements
;
// Elements in tree
/*
ulong
use_count
;
// use of this sub_tree
Number of children of this element in the RB-tree, plus 1 for this
element itself.
*/
uint16
elements
;
/*
Valid only for elements which are RB-tree roots: Number of times this
RB-tree is referred to (it is referred by SEL_ARG::next_key_part or by
SEL_TREE::keys[i] or by a temporary SEL_ARG* variable)
*/
ulong
use_count
;
Field
*
field
;
Field
*
field
;
char
*
min_value
,
*
max_value
;
// Pointer to range
char
*
min_value
,
*
max_value
;
// Pointer to range
SEL_ARG
*
left
,
*
right
,
*
next
,
*
prev
,
*
parent
,
*
next_key_part
;
SEL_ARG
*
left
,
*
right
;
/* R-B tree children */
SEL_ARG
*
next
,
*
prev
;
/* Links for bi-directional interval list */
SEL_ARG
*
parent
;
/* R-B tree parent */
SEL_ARG
*
next_key_part
;
enum
leaf_color
{
BLACK
,
RED
}
color
;
enum
leaf_color
{
BLACK
,
RED
}
color
;
enum
Type
{
IMPOSSIBLE
,
MAYBE
,
MAYBE_KEY
,
KEY_RANGE
}
type
;
enum
Type
{
IMPOSSIBLE
,
MAYBE
,
MAYBE_KEY
,
KEY_RANGE
}
type
;
...
@@ -1428,6 +1529,7 @@ SEL_ARG *SEL_ARG::clone(SEL_ARG *new_parent,SEL_ARG **next_arg)
...
@@ -1428,6 +1529,7 @@ SEL_ARG *SEL_ARG::clone(SEL_ARG *new_parent,SEL_ARG **next_arg)
}
}
increment_use_count
(
1
);
increment_use_count
(
1
);
tmp
->
color
=
color
;
tmp
->
color
=
color
;
tmp
->
elements
=
this
->
elements
;
return
tmp
;
return
tmp
;
}
}
...
@@ -5795,8 +5897,21 @@ and_all_keys(SEL_ARG *key1,SEL_ARG *key2,uint clone_flag)
...
@@ -5795,8 +5897,21 @@ and_all_keys(SEL_ARG *key1,SEL_ARG *key2,uint clone_flag)
}
}
/*
Produce a SEL_ARG graph that represents "key1 AND key2"
SYNOPSIS
key_and()
key1 First argument, root of its RB-tree
key2 Second argument, root of its RB-tree
RETURN
RB-tree root of the resulting SEL_ARG graph.
NULL if the result of AND operation is an empty interval {0}.
*/
static
SEL_ARG
*
static
SEL_ARG
*
key_and
(
SEL_ARG
*
key1
,
SEL_ARG
*
key2
,
uint
clone_flag
)
key_and
(
SEL_ARG
*
key1
,
SEL_ARG
*
key2
,
uint
clone_flag
)
{
{
if
(
!
key1
)
if
(
!
key1
)
return
key2
;
return
key2
;
...
@@ -5859,6 +5974,7 @@ key_and(SEL_ARG *key1,SEL_ARG *key2,uint clone_flag)
...
@@ -5859,6 +5974,7 @@ key_and(SEL_ARG *key1,SEL_ARG *key2,uint clone_flag)
if
((
key1
->
min_flag
|
key2
->
min_flag
)
&
GEOM_FLAG
)
if
((
key1
->
min_flag
|
key2
->
min_flag
)
&
GEOM_FLAG
)
{
{
/* TODO: why not leave one of the trees? */
key1
->
free_tree
();
key1
->
free_tree
();
key2
->
free_tree
();
key2
->
free_tree
();
return
0
;
// Can't optimize this
return
0
;
// Can't optimize this
...
@@ -6581,6 +6697,51 @@ int test_rb_tree(SEL_ARG *element,SEL_ARG *parent)
...
@@ -6581,6 +6697,51 @@ int test_rb_tree(SEL_ARG *element,SEL_ARG *parent)
return
-
1
;
// Error, no more warnings
return
-
1
;
// Error, no more warnings
}
}
/*
Count how many times SEL_ARG graph "root" refers to its part "key"
SYNOPSIS
count_key_part_usage()
root An RB-Root node in a SEL_ARG graph.
key Another RB-Root node in that SEL_ARG graph.
DESCRIPTION
The passed "root" node may refer to "key" node via root->next_key_part,
root->next->n
This function counts how many times the node "key" is referred (via
SEL_ARG::next_key_part) by
- intervals of RB-tree pointed by "root",
- intervals of RB-trees that are pointed by SEL_ARG::next_key_part from
intervals of RB-tree pointed by "root",
- and so on.
Here is an example (horizontal links represent next_key_part pointers,
vertical links - next/prev prev pointers):
+----+ $
|root|-----------------+
+----+ $ |
| $ |
| $ |
+----+ +---+ $ | +---+ Here the return value
| |- ... -| |---$-+--+->|key| will be 4.
+----+ +---+ $ | | +---+
| $ | |
... $ | |
| $ | |
+----+ +---+ $ | |
| |---| |---------+ |
+----+ +---+ $ |
| | $ |
... +---+ $ |
| |------------+
+---+ $
RETURN
Number of links to "key" from nodes reachable from "root".
*/
static
ulong
count_key_part_usage
(
SEL_ARG
*
root
,
SEL_ARG
*
key
)
static
ulong
count_key_part_usage
(
SEL_ARG
*
root
,
SEL_ARG
*
key
)
{
{
ulong
count
=
0
;
ulong
count
=
0
;
...
@@ -6598,6 +6759,20 @@ static ulong count_key_part_usage(SEL_ARG *root, SEL_ARG *key)
...
@@ -6598,6 +6759,20 @@ static ulong count_key_part_usage(SEL_ARG *root, SEL_ARG *key)
}
}
/*
Check if SEL_ARG::use_count value is correct
SYNOPSIS
SEL_ARG::test_use_count()
root The root node of the SEL_ARG graph (an RB-tree root node that
has the least value of sel_arg->part in the entire graph, and
thus is the "origin" of the graph)
DESCRIPTION
Check if SEL_ARG::use_count value is correct. See the definition of
use_count for what is "correct".
*/
void
SEL_ARG
::
test_use_count
(
SEL_ARG
*
root
)
void
SEL_ARG
::
test_use_count
(
SEL_ARG
*
root
)
{
{
uint
e_count
=
0
;
uint
e_count
=
0
;
...
...
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