Optimizer statistics can easily identify columns with more than one distinct value. After statistics are gathered a simple query against the data dictionary will return the results almost instantly.

The results will only be accurate on 10g if you use ESTIMATE_PERCENT = 100. The results will be accurate on 11g+ if you use ESTIMATE_PERCENT = 100 or AUTO_SAMPLE_SIZE.

**Code**

```
create table test_case(a varchar2(1), b number, c varchar2(3),d number,e number);
--I added a new test case, E. E has null and not-null values.
--This is a useful test because null and not-null values are counted separately.
insert into test_case
SELECT 'X' A, 5 B, 'FRI' C, NULL D, NULL E FROM DUAL UNION ALL
SELECT 'X' A, 3 B, 'FRI' C, NULL D, NULL E FROM DUAL UNION ALL
SELECT 'X' A, 7 B, 'TUE' C, NULL D, 1 E FROM DUAL;
--Gather stats with default settings, which uses AUTO_SAMPLE_SIZE.
--One advantage of this method is that you can quickly get information for many
--tables at one time.
begin
dbms_stats.gather_schema_stats(user);
end;
/
--All columns with more than one distinct value.
--Note that nulls and not-nulls are counted differently.
--Not-nulls are counted distinctly, nulls are counted total.
select owner, table_name, column_name
from dba_tab_columns
where owner = user
and num_distinct + least(num_nulls, 1) <= 1
order by column_name;
OWNER TABLE_NAME COLUMN_NAME
------- ---------- -----------
JHELLER TEST_CASE A
JHELLER TEST_CASE D
```

**Performance**

On 11g, this method might be about as fast as mucio's SQL statement. Options like `cascade => false`

would improve performance by not analyzing indexes.

But the great thing about this method is that it also produces useful statistics. If the system is already gathering statistics at regular intervals the hard work may already be done.

**Details about AUTO_SAMPLE_SIZE algorithm**

AUTO_SAMPLE_SIZE was completely changed in 11g. It does not use sampling for estimating number of distinct values (NDV). Instead it scans the whole table and uses a hash-based distinct algorithm. This algorithm does not require large amounts of memory or temporary tablespace. It's much faster to read the whole table than to sort even a small part of it. The Oracle Optimizer blog has a good description of the algorithm here. For even more details, see this presentation by Amit Podder. (You'll want to scan through that PDF if you want to verify the details in my next section.)

**Possibility of a wrong result**

Although the new algorithm does not use a simple sampling algorithm it still does not count the number of distinct values 100% correctly. It's easy to find cases where the estimated number of distinct values is not the same as the actual. But if the number of distinct values are clearly inaccurate, how can they be trusted in this solution?

The potential inaccuracy comes from two sources - hash collisions and synopsis splitting. Synopsis splitting is the main source of inaccuracy but does not apply here. It only happens when there are 13864 distinct values. And it never throws out *all* of the values, the final estimate will certainly be much larger than 1.

The only real concern is what are the chances of there being 2 distinct values with a hash collision. With a 64-bit hash the chance could be as low as 1 in 18,446,744,073,709,551,616. Unfortunately I don't know the details of their hashing algorithm and don't know the real probability. I was unable to produce any collisions from some simple testing and from previous real-life tests. (One of my tests was to use large values, since some statistics operations only use the first N bytes of data.)

Now also consider that this will only happen if *all* of the distinct values in the table collide. What are the chances of there being a table with *only* two values that just happen to collide? Probably much less than the chance of winning the lottery and getting struck by a meteorite at the same time.

`colA_indicator`

,`colB_indicator`

values of Y or N?