Your query is quite convoluted. I think you just want to count the combinations of
item. If so, this is a simple aggregation:
select id, item, count(*)
from Table1 a
group by id, item;
If you want all ids and items to appear, then use a driver table:
select driver.id, driver.item, coalesce(count(t1.id), 0)
from (select id.id, item.item
from (select distinct id from Table1) id cross join
(select distinct item from Table1) item
) driver left outer join
on driver.id = t1.id and driver.item = t1.item
group by driver.id, driver.item;
The original query has this statement:
(SELECT DISTINCT a.id,b.item FROM Table1 a, Table1 b) a
This is doing full cartesian product and then doing a distinct. So, if your table has 100,000 rows, then the intermediate table has 10,000,000,000 rows for the distinct (I don't think MySQL optimizes this a bit better). Doing the distinct first (as for the driver) greatly reduces the volume of data.
There are a class of SQL questions where you need to look at all combinations of two or more items and then determine values for everyone (even those that don't exist in the data) or find those that are not in the data. These problems pose the same problem: how do you get information about values not in the data?
The solution that I advocate is to create a table that has all possible combinations, and then use
left [outer] join for the remaining tables. I call this the "driver" table, because the rows in this query "drive" the query by defining the population for subsequent joins.
This terminology is fairly consistent with the reference in the comment. The comment is using the term from the optimizer perspective. Some join algorithms -- particularly nested loop and index lookup -- treat the two sides of the join differently; for these, one side is the "driving/driver" table. For instance, when joining from a large table to a small reference table, the large table is the driving table and the other table is accessed through an index. Other join algorithms -- such as merge join and hash joins (in general) -- treat both sides the same, so the concept is less applicable there.
From the logical perspective, I'm using it to mean the query that defines the population. An important similarity is that for a left/right outer join, both definitions are, in practice, the same. The optimizer would typically choose the first table in a
left join as the "driver", because it defines the output rows.