跳到主要内容

How to Write Aggregate Functions

How to write aggregate functions

Databend allows us to write custom aggregate functions through rust code. It's not an easy way because you need to be a rustacean first. Databend has a plan to support writing UDAFs in other languages(like js, web assembly) in the future.

In this section we will talk about how to write aggregate functions in Databend.

AggregateFunction trait introduction

All aggregate functions implement AggregateFunction trait, and we register them into a global static FunctionFactory, the factory is just an index map and the key is the name of the aggregate function.

提示

Function name in Databend is case-insensitive.

pub trait AggregateFunction: fmt::Display + Sync + Send {
...
}

### Understand the functions

- The function `name` indicates the name of this function, such as `sum`, `min`.
- The function `return_type` indicates the return type of the function, it may vary with different arguments, such as `sum(int8)` -> `int64`, `sum(uint8)` -> `uint64`, `sum(float64)` -> `float64`.
- The function `nullable` indicates whether the `return_type` is nullable or not.

Before we start to introduce the function `init_state`, let's ask a question first:

> what's aggregate function state?

It indicates the temporary results of an aggregate function. Because an aggregate function accumulates data in columns block by block and there will be some intermediate results after the aggregation. Therefore, the state must be mergeable, serializable.

For example, in the `avg` aggregate function, we can represent the state like:

```rust
struct AggregateAvgState<T: PrimitiveType> {
#[serde(bound(deserialize = "T: DeserializeOwned"))]
pub value: T,
pub count: u64,
}

  • The function init_state initializes the aggregate function state, we ensure the memory is already allocated, and we just need to initial the state with the initial value.
  • The function state_layout indicates the memory layout of the state.
  • The function accumulate is used in aggregation with a single batch, which means the whole block can be aggregated in a single state, no other keys. The SQL query, which applies aggregation without group-by columns, will hit this function.

Noted that the argument _arrays is the function arguments, we can safely get the array by index without index bound check because we must validate the argument numbers and types in function constructor.

The _input_rows is the rows of the current block, and it may be useful when the _arrays is empty, e.g., count() function.

  • The function accumulate_keys is similar to accumulate, but we must take into consideration the keys and offsets, for which each key represents a unique memory address named place.
  • The function serialize serializes state into binary.
  • The function deserialize deserializes state from binary.
  • The function merge, can be used to merge other state into current state.
  • The function merge_result, can be used to represent the aggregate function state into one-row field.

Example

Let's take an example of aggregate function sum.

It's declared as AggregateSumFunction<T, SumT>, we can accept varying integer types like u8, i8. T and SumT is logic types which implement DFPrimitiveType. e.g., T is u8 and SumT must be u64.

Also, we can dispatch it using macros by matching the types of the arguments. Take a look at the with_match_primitive_type to understand the dispatch macros.

The AggregateSumState will be

struct AggregateSumState<T> {
pub value: T,
}

The generic T is from SumT.

Let's take into the function accumulate_keys, because this is the only function that a little hard to understand in this case.

fn accumulate_keys(
&self,
places: &[StateAddr],
offset: usize,
columns: &[ColumnRef],
_input_rows: usize,
) -> Result<()> {
if columns[0].data_type().data_type_id() == TypeID::Boolean {
// boolean cast into u8 column
// ...
} else {
let darray: &PrimitiveColumn<T> = unsafe { Series::static_cast(&columns[0]) };
darray.iter().zip(places.iter()).for_each(|(c, place)| {
let place = place.next(offset);
let state = place.get::<AggregateSumState<SumT>>();
state.add(c.as_());
});
}

Ok(())
}

The places is the memory address of the first state in this row, so we can get the address of AggregateSumState<T> using places[row] + offset, then using place.get::<AggregateSumState<SumT>>() to get the value of the corresponding state.

Since we already know the array type of this function, we can safely cast it to arrow's PrimitiveArray<T>, here we make two branches to reduce the branch prediction of CPU, null and no_null. In no_null case, we just iterate the array and apply the sum, this is good for compiler to optimize the codes into vectorized codes.

Ok, this example is pretty easy. If you already read this, you may have the ability to write a new function.

Testing

To be a good engineer, don't forget to test your codes, please add unit tests and stateless tests after you finish the new aggregate functions.

SELECT sum(number), sum(-1), sum(2.3)  from numbers(3);
+-------------+---------+--------------------+
| sum(number) | sum(-1) | sum(2.3) |
+-------------+---------+--------------------+
| 3 | -3 | 6.8999999999999995 |
+-------------+---------+--------------------+

Refer to other examples

As you see, adding a new aggregate function in Databend is not as hard as you think. Before you start to add one, please refer to other aggregate function examples, such as min, count, max, avg.

Summary

We welcome all community users to contribute more powerful functions to Databend. If you find any problems, feel free to open an issue in GitHub, we will use our best efforts to help you.