Starting with table

payments
+------------------------------+
| customer_id | amount | item |
| 5 | 10 | book |
| 5 | 71 | mouse |
| 7 | 13 | cover |
| 7 | 22 | cable |
| 7 | 19 | book |
+------------------------------+

```
SELECT customer_id,
AVG(amount) OVER (PARTITION BY customer_id) AS avg_amount,
item,
FROM payments`
```

we get

+----------------------------------+
| customer_id | avg_amount | item |
| 5 | 40.5 | book |
| 5 | 40.5 | mouse |
| 7 | 18 | cover |
| 7 | 18 | cable |
| 7 | 18 | book |
+----------------------------------+

`AVG`

being an aggregate function, it can act as a window function. However not all window functions are aggregate functions. The aggregate functions are the non-sophisticated window functions.

In the query above, let's not use the built-in `AVG`

function and use our own implementation. Does the same, just implemented by the user. The query above becomes:

```
SELECT customer_id,
my_avg(amount) OVER (PARTITION BY customer_id) AS avg_amount,
item,
FROM payments`
```

The only difference from the former query is that `AVG`

has been replaced with `my_avg`

. We now need to implement our custom function.

# On how to compute the average

Sum up all the elements, then divide by the number of elements. For `customer_id`

of 7, that would be `(13 + 22 + 19) / 3 = 18`

.
We can devide it in:

- a step-by-step accumulation -- the sum.
- a final operation -- division.

# On how the aggregate function gets to the result

The average is computed in steps. Only the last value is necessary.
Start with an initial value of 0.

- Feed 13. Compute the intermediate/accumulated sum, which is 13.
- Feed 22. Compute the accumulated sum, which needs the previous sum plus this element:
`13 + 22 = 35`

- Feed 19. Compute the accumulated sum, which needs the previous sum plus this element:
`35 + 19 = 54`

. This is the total that needs to be divided by the number of element (3).
- The result of step 3. is fed to another function, that knows how to divide the accumulated sum by the number of elements

What happened here is that the state started with the initial value of 0 and was changed with every step, then passed to the next step.

State travels between steps for as long as there is data. When all data is consumed state goes to a final function (terminal operation). We want the state to contain all the information needed for the accumulator as well as by the terminal operation.

In the specific case of computing the average, the terminal operation needs to know how many elements the accumulator worked with because it needs to divide by that. For that reason, the state needs to include both the accumulated sum and the number of elements.

We need a tuple that will contain both. Pre-defined `POINT`

PostgreSQL type to the rescue. POINT(5, 89) means an accumulated sum of 5 elements that has the value of 89. The initial state will be a POINT(0,0).

The accumulator is implemented in what's called a *state function*. The terminal operation is implemented in what's called a *final function*.

When defining a custom aggregate function we need to specify:

- the aggregate function name and return type
- the initial state
- the type of the state that the infrastructure will pass between steps and to the final function
- a state function -- knows how to perform the accumulation steps
- a final function -- knows how to perform the terminal operation. Not always needed (e.g. in a custom implementation of SUM the final value of the accumulated sum is the result.)

Here's the definition for the custom aggregate function.

```
CREATE AGGREGATE my_avg (NUMERIC) ( -- NUMERIC is what the function returns
initcond = '(0,0)', -- this is the initial state of type POINT
stype = POINT, -- this is the type of the state that will be passed between steps
sfunc = my_acc, -- this is the function that knows how to compute a new average from existing average and new element. Takes in the state (type POINT) and an element for the step (type NUMERIC)
finalfunc my_final_func -- returns the result for the aggregate function. Takes in the state of type POINT (like all other steps) and returns the result as what the aggregate function returns - NUMERIC
);
```

The only thing left is to define two functions `my_acc`

and `my_final_func`

.

```
CREATE FUNCTION my_acc (state POINT, elem_for_step NUMERIC) -- performs accumulated sum
RETURNS POINT
LANGUAGE SQL
AS $$
-- state[0] is the number of elements, state[1] is the accumulated sum
SELECT POINT(state[0]+1, state[1] + elem_for_step);
$$;
CREATE FUNCTION my_final_func (POINT) -- performs devision and returns final value
RETURNS NUMERIC
LANGUAGE SQL
AS $$
-- $1[1] is the sum, $1[0] is the number of elements
SELECT ($1[1]/$1[0])::NUMERIC;
$$;
```

Now that the functions are available `CREATE AGGREGATE`

defined above will run successfully. Now that we have the aggregate defined, the query based on `my_avg`

instead of the built-in `AVG`

can be run:

```
SELECT customer_id,
my_avg(amount) OVER (PARTITION BY customer_id) AS avg_amount,
item,
FROM payments`
```

The results are identical with what you get when using the built-in `AVG`

.

The PostgreSQL documentation suggests that the users are limited to implementing user-defined aggregate functions:

In addition to these [pre-defined window] functions, any built-in or user-defined general-purpose or statistical aggregate (i.e., not ordered-set or hypothetical-set aggregates) can be used as a window function;

What I suspect `ordered-set or hypothetical-set aggregates`

means:

- the value returned is identical to all other rows (e.g.
`AVG`

and `SUM`

. In contrast `RANK`

returns different values for all rows in group depending on more sophisticated criteria)
- it makes no sense to ORDER BY when PARTITIONing because the values are the same for all rows anyway. In contrast we want to
`ORDER BY`

when using `RANK()`

Query:

```
SELECT customer_id, item, rank() OVER (PARTITION BY customer_id ORDER BY amount desc) FROM payments;
```

# Geometric mean

The following is a user-defined aggregate function that I found no built-in aggregate for and may be useful to some.

The state function computes the average of the natural logarithms of the terms.

The final function raises constant `e`

to whatever the accumulator provides.

```
CREATE OR REPLACE FUNCTION sum_of_log(state POINT, curr_val NUMERIC)
RETURNS POINT
LANGUAGE SQL
AS $$
SELECT POINT(state[0] + 1,
(state[1] * state[0]+ LN(curr_val))/(state[0] + 1));
$$;
CREATE OR REPLACE FUNCTION e_to_avg_of_log(POINT)
RETURNS NUMERIC
LANGUAGE SQL
AS $$
select exp($1[1])::NUMERIC;
$$;
CREATE AGGREGATE geo_mean (NUMBER)
(
stype = NUMBER,
initcond = '(0,0)', -- represent POINT value
sfunc = sum_of_log,
finalfunc = e_to_avg_of_log
);
```

`order by`

in your window definition you get a running average without any hassle. There is no need to use "rows between": sqlfiddle.com/#!12/902c3/1