use num_traits::ToPrimitive;
use reifydb_core::value::column::{ColumnWithName, buffer::ColumnBuffer, columns::Columns};
use reifydb_type::value::r#type::{Type, input_types::InputTypes};
use crate::routine::{Function, FunctionKind, Routine, RoutineInfo, context::FunctionContext, error::RoutineError};
pub struct Atan2 {
info: RoutineInfo,
}
impl Default for Atan2 {
fn default() -> Self {
Self::new()
}
}
impl Atan2 {
pub fn new() -> Self {
Self {
info: RoutineInfo::new("math::atan2"),
}
}
}
fn numeric_to_f64(data: &ColumnBuffer, i: usize) -> Option<f64> {
match data {
ColumnBuffer::Int1(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Int2(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Int4(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Int8(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Int16(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Uint1(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Uint2(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Uint4(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Uint8(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Uint16(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Float4(c) => c.get(i).map(|&v| v as f64),
ColumnBuffer::Float8(c) => c.get(i).copied(),
ColumnBuffer::Int {
container,
..
} => container.get(i).map(|v| v.0.to_f64().unwrap_or(0.0)),
ColumnBuffer::Uint {
container,
..
} => container.get(i).map(|v| v.0.to_f64().unwrap_or(0.0)),
ColumnBuffer::Decimal {
container,
..
} => container.get(i).map(|v| v.0.to_f64().unwrap_or(0.0)),
_ => None,
}
}
impl<'a> Routine<FunctionContext<'a>> for Atan2 {
fn info(&self) -> &RoutineInfo {
&self.info
}
fn return_type(&self, _input_types: &[Type]) -> Type {
Type::Float8
}
fn execute(&self, ctx: &mut FunctionContext<'a>, args: &Columns) -> Result<Columns, RoutineError> {
if args.len() != 2 {
return Err(RoutineError::FunctionArityMismatch {
function: ctx.fragment.clone(),
expected: 2,
actual: args.len(),
});
}
let y_col = &args[0];
let x_col = &args[1];
let (y_data, y_bitvec) = y_col.unwrap_option();
let (x_data, x_bitvec) = x_col.unwrap_option();
let row_count = y_data.len();
if !y_data.get_type().is_number() {
return Err(RoutineError::FunctionInvalidArgumentType {
function: ctx.fragment.clone(),
argument_index: 0,
expected: InputTypes::numeric().expected_at(0).to_vec(),
actual: y_data.get_type(),
});
}
if !x_data.get_type().is_number() {
return Err(RoutineError::FunctionInvalidArgumentType {
function: ctx.fragment.clone(),
argument_index: 1,
expected: InputTypes::numeric().expected_at(0).to_vec(),
actual: x_data.get_type(),
});
}
let mut result = Vec::with_capacity(row_count);
let mut res_bitvec = Vec::with_capacity(row_count);
for i in 0..row_count {
match (numeric_to_f64(y_data, i), numeric_to_f64(x_data, i)) {
(Some(y), Some(x)) => {
result.push(y.atan2(x));
res_bitvec.push(true);
}
_ => {
result.push(0.0);
res_bitvec.push(false);
}
}
}
let result_data = ColumnBuffer::float8_with_bitvec(result, res_bitvec);
let combined_bitvec = match (y_bitvec, x_bitvec) {
(Some(y_bv), Some(x_bv)) => Some(y_bv.and(x_bv)),
(Some(y_bv), None) => Some(y_bv.clone()),
(None, Some(x_bv)) => Some(x_bv.clone()),
(None, None) => None,
};
let final_data = if let Some(bv) = combined_bitvec {
ColumnBuffer::Option {
inner: Box::new(result_data),
bitvec: bv,
}
} else {
result_data
};
Ok(Columns::new(vec![ColumnWithName::new(ctx.fragment.clone(), final_data)]))
}
}
impl Function for Atan2 {
fn kinds(&self) -> &[FunctionKind] {
&[FunctionKind::Scalar]
}
}