Commit 62942018 authored by sergefp@mysql.com's avatar sergefp@mysql.com

WL#2985 "Partition-pruning", "range walking" addition: better comments.

parent e40e1003
......@@ -690,11 +690,10 @@ class partition_info : public Sql_alloc
/*
A bitmap of partitions used by the current query.
Usage pattern:
* It is guaranteed that all partitions are set to be unused on query start.
* The handler->extra(HA_EXTRA_RESET) call at query start/end sets all
partitions to be unused.
* Before index/rnd_init(), partition pruning code sets the bits for used
partitions.
* The handler->extra(HA_EXTRA_RESET) call at query end sets all partitions
to be unused.
*/
MY_BITMAP used_partitions;
......
......@@ -2115,7 +2115,7 @@ int SQL_SELECT::test_quick_select(THD *thd, key_map keys_to_use,
The list of intervals we'll obtain will look like this:
((t1.a, t1.b) = (1,'foo')),
((t1.a, t1.b) = (2,'bar')),
((t1,a, t1.b) > (10,'zz')) (**)
((t1,a, t1.b) > (10,'zz'))
2. for each interval I
{
......@@ -2574,30 +2574,95 @@ int find_used_partitions_imerge(PART_PRUNE_PARAM *ppar, SEL_IMERGE *imerge)
This function
* recursively walks the SEL_ARG* tree collecting partitioning "intervals"
* finds the partitions one needs to use to get rows in these intervals
* marks these partitions as used
NOTES
WHAT IS CONSIDERED TO BE "INTERVALS"
A partition pruning "interval" is equivalent to condition in one of the
forms:
* marks these partitions as used.
The next session desribes the process in greater detail.
IMPLEMENTATION
TYPES OF RESTRICTIONS THAT WE CAN OBTAIN PARTITIONS FOR
We can find out which [sub]partitions to use if we obtain restrictions on
[sub]partitioning fields in the following form:
1. "partition_field1=const1 AND ... AND partition_fieldN=constN"
1.1 Same as (1) but for subpartition fields
If partitioning supports interval analysis (i.e. partitioning is a
function of a single table field, and partition_info::
get_part_iter_for_interval != NULL), then we can also use condition in
this form:
2. "const1 <=? partition_field <=? const2"
2.1 Same as (2) but for subpartition_field
INFERRING THE RESTRICTIONS FROM SEL_ARG TREE
"partition_field1=const1 AND ... AND partition_fieldN=constN" (1)
"subpartition_field1=const1 AND ... AND subpartition_fieldN=constN" (2)
"(1) AND (2)" (3)
The below is an example of what SEL_ARG tree may represent:
In (1) and (2) all [sub]partitioning fields must be used, and "x=const"
includes "x IS NULL".
(start)
| $
| Partitioning keyparts $ subpartitioning keyparts
| $
| ... ... $
| | | $
| +---------+ +---------+ $ +-----------+ +-----------+
\-| par1=c1 |--| par2=c2 |-----| subpar1=c3|--| subpar2=c5|
+---------+ +---------+ $ +-----------+ +-----------+
| $ | |
| $ | +-----------+
| $ | | subpar2=c6|
| $ | +-----------+
| $ |
| $ +-----------+ +-----------+
| $ | subpar1=c4|--| subpar2=c8|
| $ +-----------+ +-----------+
| $
| $
+---------+ $ +------------+ +------------+
| par1=c2 |------------------| subpar1=c10|--| subpar2=c12|
+---------+ $ +------------+ +------------+
| $
... $
The up-down connections are connections via SEL_ARG::left and
SEL_ARG::right. A horizontal connection to the right is the
SEL_ARG::next_key_part connection.
If partitioning is performed using
PARTITION BY RANGE(unary_monotonic_func(single_partition_field)),
then the following is also an interval:
find_used_partitions() traverses the entire tree via recursion on
* SEL_ARG::next_key_part (from left to right on the picture)
* SEL_ARG::left|right (up/down on the pic). Left-right recursion is
performed for each depth level.
Recursion descent on SEL_ARG::next_key_part is used to accumulate (in
ppar->arg_stack) constraints on partitioning and subpartitioning fields.
For the example in the above picture, one of stack states is:
in find_used_partitions(key_tree = "subpar2=c5") (***)
in find_used_partitions(key_tree = "subpar1=c3")
in find_used_partitions(key_tree = "par2=c2") (**)
in find_used_partitions(key_tree = "par1=c1")
in prune_partitions(...)
We apply partitioning limits as soon as possible, e.g. when we reach the
depth (**), we find which partition(s) correspond to "par1=c1 AND par2=c2",
and save them in ppar->part_iter.
When we reach the depth (***), we find which subpartition(s) correspond to
"subpar1=c3 AND subpar2=c5", and then mark appropriate subpartitions in
appropriate subpartitions as used.
It is possible that constraints on some partitioning fields are missing.
For the above example, consider this stack state:
in find_used_partitions(key_tree = "subpar2=c12") (***)
in find_used_partitions(key_tree = "subpar1=c10")
in find_used_partitions(key_tree = "par1=c2")
in prune_partitions(...)
Here we don't have constraints for all partitioning fields. Since we've
never set the ppar->part_iter to contain used set of partitions, we use
its default "all partitions" value. We get subpartition id for
"subpar1=c3 AND subpar2=c5", and mark that subpartition as used in every
partition.
The inverse is also possible: we may get constraints on partitioning
fields, but not constraints on subpartitioning fields. In that case,
calls to find_used_partitions() with depth below (**) will return -1,
and we will mark entire partition as used.
" const1 OP1 single_partition_field OP2 const2" (4)
where OP1 and OP2 are '<' OR '<=', and const_i can be +/- inf.
Everything else is not a partition pruning "interval".
TODO
Replace recursion on SEL_ARG::left and SEL_ARG::right with a loop
RETURN
1 OK, one or more [sub]partitions are marked as used.
......
......@@ -3673,11 +3673,11 @@ typedef uint32 (*get_endpoint_func)(partition_info*, bool left_endpoint,
DESCRIPTION
Initialize partition set iterator to walk over the interval in
ordered-list-of-partitions (for RANGE partitioning) or
ordered-list-of-list-constants (for LIST partitioning) space.
ordered-array-of-partitions (for RANGE partitioning) or
ordered-array-of-list-constants (for LIST partitioning) space.
IMPLEMENTATION
This function is applied when partitioning is done by
This function is used when partitioning is done by
<RANGE|LIST>(ascending_func(t.field)), and we can map an interval in
t.field space into a sub-array of partition_info::range_int_array or
partition_info::list_array (see get_partition_id_range_for_endpoint,
......@@ -3686,7 +3686,7 @@ typedef uint32 (*get_endpoint_func)(partition_info*, bool left_endpoint,
The function performs this interval mapping, and sets the iterator to
traverse the sub-array and return appropriate partitions.
RETURN
RETURN
0 - No matching partitions (iterator not initialized)
1 - Ok, iterator intialized for traversal of matching partitions.
-1 - All partitions would match (iterator not initialized)
......@@ -3760,7 +3760,7 @@ int get_part_iter_for_interval_via_mapping(partition_info *part_info,
/*
Partitioning Interval Analysis: Initialize iterator to walk integer interval
Partitioning Interval Analysis: Initialize iterator to walk field interval
SYNOPSIS
get_part_iter_for_interval_via_walking()
......@@ -3776,7 +3776,8 @@ int get_part_iter_for_interval_via_mapping(partition_info *part_info,
DESCRIPTION
Initialize partition set iterator to walk over interval in integer field
space. That is, for "const1 <=? t.field <=? const2" interval, initialize
the iterator to do this:
the iterator to return a set of [sub]partitions obtained with the
following procedure:
get partition id for t.field = const1, return it
get partition id for t.field = const1+1, return it
... t.field = const1+2, ...
......@@ -3790,7 +3791,7 @@ int get_part_iter_for_interval_via_mapping(partition_info *part_info,
"c1 <=? t.field <=? c2", where c1 and c2 are finite.
Intervals with +inf/-inf, and [NULL, c1] interval can be processed but
that is more tricky and I don't have time to do it right now.
Additionally we have these requirements:
* number of values in the interval must be less then number of
[sub]partitions, and
......@@ -3799,7 +3800,7 @@ int get_part_iter_for_interval_via_mapping(partition_info *part_info,
The rationale behind these requirements is that if they are not met
we're likely to hit most of the partitions and traversing the interval
will only add overhead. So it's better return "all partitions used" in
this case.
that case.
RETURN
0 - No matching partitions, iterator not initialized
......@@ -3917,7 +3918,7 @@ uint32 get_next_partition_id_range(PARTITION_ITERATOR* part_iter)
part_iter Partition set iterator structure
DESCRIPTION
This is special implementation of PARTITION_ITERATOR::get_next() for
This implementation of PARTITION_ITERATOR::get_next() is special for
LIST partitioning: it enumerates partition ids in
part_info->list_array[i] where i runs over [min_idx, max_idx] interval.
......@@ -3937,13 +3938,16 @@ uint32 get_next_partition_id_list(PARTITION_ITERATOR *part_iter)
/*
PARTITION_ITERATOR::get_next implementation: walk over integer interval
PARTITION_ITERATOR::get_next implementation: walk over field-space interval
SYNOPSIS
get_next_partition_via_walking()
part_iter Partitioning iterator
DESCRIPTION
This implementation of PARTITION_ITERATOR::get_next() returns ids of
partitions that contain records with partitioning field value within
[start_val, end_val] interval.
RETURN
partition id
......
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