datafusion_physical_expr/expressions/
negative.rsuse std::any::Any;
use std::hash::{Hash, Hasher};
use std::sync::Arc;
use crate::physical_expr::down_cast_any_ref;
use crate::PhysicalExpr;
use arrow::{
compute::kernels::numeric::neg_wrapping,
datatypes::{DataType, Schema},
record_batch::RecordBatch,
};
use datafusion_common::{plan_err, Result};
use datafusion_expr::interval_arithmetic::Interval;
use datafusion_expr::sort_properties::ExprProperties;
use datafusion_expr::{
type_coercion::{is_interval, is_null, is_signed_numeric, is_timestamp},
ColumnarValue,
};
#[derive(Debug, Hash)]
pub struct NegativeExpr {
arg: Arc<dyn PhysicalExpr>,
}
impl NegativeExpr {
pub fn new(arg: Arc<dyn PhysicalExpr>) -> Self {
Self { arg }
}
pub fn arg(&self) -> &Arc<dyn PhysicalExpr> {
&self.arg
}
}
impl std::fmt::Display for NegativeExpr {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
write!(f, "(- {})", self.arg)
}
}
impl PhysicalExpr for NegativeExpr {
fn as_any(&self) -> &dyn Any {
self
}
fn data_type(&self, input_schema: &Schema) -> Result<DataType> {
self.arg.data_type(input_schema)
}
fn nullable(&self, input_schema: &Schema) -> Result<bool> {
self.arg.nullable(input_schema)
}
fn evaluate(&self, batch: &RecordBatch) -> Result<ColumnarValue> {
let arg = self.arg.evaluate(batch)?;
match arg {
ColumnarValue::Array(array) => {
let result = neg_wrapping(array.as_ref())?;
Ok(ColumnarValue::Array(result))
}
ColumnarValue::Scalar(scalar) => {
Ok(ColumnarValue::Scalar((scalar.arithmetic_negate())?))
}
}
}
fn children(&self) -> Vec<&Arc<dyn PhysicalExpr>> {
vec![&self.arg]
}
fn with_new_children(
self: Arc<Self>,
children: Vec<Arc<dyn PhysicalExpr>>,
) -> Result<Arc<dyn PhysicalExpr>> {
Ok(Arc::new(NegativeExpr::new(Arc::clone(&children[0]))))
}
fn dyn_hash(&self, state: &mut dyn Hasher) {
let mut s = state;
self.hash(&mut s);
}
fn evaluate_bounds(&self, children: &[&Interval]) -> Result<Interval> {
Interval::try_new(
children[0].upper().arithmetic_negate()?,
children[0].lower().arithmetic_negate()?,
)
}
fn propagate_constraints(
&self,
interval: &Interval,
children: &[&Interval],
) -> Result<Option<Vec<Interval>>> {
let child_interval = children[0];
let negated_interval = Interval::try_new(
interval.upper().arithmetic_negate()?,
interval.lower().arithmetic_negate()?,
)?;
Ok(child_interval
.intersect(negated_interval)?
.map(|result| vec![result]))
}
fn get_properties(&self, children: &[ExprProperties]) -> Result<ExprProperties> {
Ok(ExprProperties {
sort_properties: -children[0].sort_properties,
range: children[0].range.clone().arithmetic_negate()?,
})
}
}
impl PartialEq<dyn Any> for NegativeExpr {
fn eq(&self, other: &dyn Any) -> bool {
down_cast_any_ref(other)
.downcast_ref::<Self>()
.map(|x| self.arg.eq(&x.arg))
.unwrap_or(false)
}
}
pub fn negative(
arg: Arc<dyn PhysicalExpr>,
input_schema: &Schema,
) -> Result<Arc<dyn PhysicalExpr>> {
let data_type = arg.data_type(input_schema)?;
if is_null(&data_type) {
Ok(arg)
} else if !is_signed_numeric(&data_type)
&& !is_interval(&data_type)
&& !is_timestamp(&data_type)
{
plan_err!("Negation only supports numeric, interval and timestamp types")
} else {
Ok(Arc::new(NegativeExpr::new(arg)))
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::expressions::{col, Column};
use arrow::array::*;
use arrow::datatypes::*;
use arrow_schema::DataType::{Float32, Float64, Int16, Int32, Int64, Int8};
use datafusion_common::cast::as_primitive_array;
use datafusion_common::DataFusionError;
use paste::paste;
macro_rules! test_array_negative_op {
($DATA_TY:tt, $($VALUE:expr),* ) => {
let schema = Schema::new(vec![Field::new("a", DataType::$DATA_TY, true)]);
let expr = negative(col("a", &schema)?, &schema)?;
assert_eq!(expr.data_type(&schema)?, DataType::$DATA_TY);
assert!(expr.nullable(&schema)?);
let mut arr = Vec::new();
let mut arr_expected = Vec::new();
$(
arr.push(Some($VALUE));
arr_expected.push(Some(-$VALUE));
)+
arr.push(None);
arr_expected.push(None);
let input = paste!{[<$DATA_TY Array>]::from(arr)};
let expected = &paste!{[<$DATA_TY Array>]::from(arr_expected)};
let batch =
RecordBatch::try_new(Arc::new(schema.clone()), vec![Arc::new(input)])?;
let result = expr.evaluate(&batch)?.into_array(batch.num_rows()).expect("Failed to convert to array");
let result =
as_primitive_array(&result).expect(format!("failed to downcast to {:?}Array", $DATA_TY).as_str());
assert_eq!(result, expected);
};
}
#[test]
fn array_negative_op() -> Result<()> {
test_array_negative_op!(Int8, 2i8, 1i8);
test_array_negative_op!(Int16, 234i16, 123i16);
test_array_negative_op!(Int32, 2345i32, 1234i32);
test_array_negative_op!(Int64, 23456i64, 12345i64);
test_array_negative_op!(Float32, 2345.0f32, 1234.0f32);
test_array_negative_op!(Float64, 23456.0f64, 12345.0f64);
Ok(())
}
#[test]
fn test_evaluate_bounds() -> Result<()> {
let negative_expr = NegativeExpr {
arg: Arc::new(Column::new("a", 0)),
};
let child_interval = Interval::make(Some(-2), Some(1))?;
let negative_expr_interval = Interval::make(Some(-1), Some(2))?;
assert_eq!(
negative_expr.evaluate_bounds(&[&child_interval])?,
negative_expr_interval
);
Ok(())
}
#[test]
fn test_propagate_constraints() -> Result<()> {
let negative_expr = NegativeExpr {
arg: Arc::new(Column::new("a", 0)),
};
let original_child_interval = Interval::make(Some(-2), Some(3))?;
let negative_expr_interval = Interval::make(Some(0), Some(4))?;
let after_propagation = Some(vec![Interval::make(Some(-2), Some(0))?]);
assert_eq!(
negative_expr.propagate_constraints(
&negative_expr_interval,
&[&original_child_interval]
)?,
after_propagation
);
Ok(())
}
#[test]
fn test_negation_valid_types() -> Result<()> {
let negatable_types = [
Int8,
DataType::Timestamp(TimeUnit::Second, None),
DataType::Interval(IntervalUnit::YearMonth),
];
for negatable_type in negatable_types {
let schema = Schema::new(vec![Field::new("a", negatable_type, true)]);
let _expr = negative(col("a", &schema)?, &schema)?;
}
Ok(())
}
#[test]
fn test_negation_invalid_types() -> Result<()> {
let schema = Schema::new(vec![Field::new("a", DataType::Utf8, true)]);
let expr = negative(col("a", &schema)?, &schema).unwrap_err();
matches!(expr, DataFusionError::Plan(_));
Ok(())
}
}