use kernel::PARENT_KERNELS;
use vortex_error::VortexResult;
use vortex_error::vortex_bail;
use vortex_error::vortex_ensure;
use vortex_error::vortex_panic;
use crate::ArrayRef;
use crate::ExecutionCtx;
use crate::ExecutionResult;
use crate::array::Array;
use crate::array::ArrayView;
use crate::array::VTable;
use crate::arrays::primitive::PrimitiveData;
use crate::buffer::BufferHandle;
use crate::dtype::DType;
use crate::dtype::PType;
use crate::serde::ArrayChildren;
use crate::validity::Validity;
mod kernel;
mod operations;
mod validity;
use std::hash::Hasher;
use vortex_buffer::Alignment;
use vortex_session::VortexSession;
use crate::Precision;
use crate::array::ArrayId;
use crate::arrays::primitive::array::SLOT_NAMES;
use crate::arrays::primitive::compute::rules::RULES;
use crate::hash::ArrayEq;
use crate::hash::ArrayHash;
pub type PrimitiveArray = Array<Primitive>;
impl ArrayHash for PrimitiveData {
fn array_hash<H: Hasher>(&self, state: &mut H, precision: Precision) {
self.buffer.array_hash(state, precision);
}
}
impl ArrayEq for PrimitiveData {
fn array_eq(&self, other: &Self, precision: Precision) -> bool {
self.buffer.array_eq(&other.buffer, precision)
}
}
impl VTable for Primitive {
type ArrayData = PrimitiveData;
type OperationsVTable = Self;
type ValidityVTable = Self;
fn id(&self) -> ArrayId {
Self::ID
}
fn nbuffers(_array: ArrayView<'_, Self>) -> usize {
1
}
fn buffer(array: ArrayView<'_, Self>, idx: usize) -> BufferHandle {
match idx {
0 => array.buffer_handle().clone(),
_ => vortex_panic!("PrimitiveArray buffer index {idx} out of bounds"),
}
}
fn buffer_name(_array: ArrayView<'_, Self>, idx: usize) -> Option<String> {
match idx {
0 => Some("values".to_string()),
_ => None,
}
}
fn serialize(
_array: ArrayView<'_, Self>,
_session: &VortexSession,
) -> VortexResult<Option<Vec<u8>>> {
Ok(Some(vec![]))
}
fn validate(
&self,
data: &PrimitiveData,
dtype: &DType,
len: usize,
slots: &[Option<ArrayRef>],
) -> VortexResult<()> {
let DType::Primitive(_, nullability) = dtype else {
vortex_bail!("Expected primitive dtype, got {dtype:?}");
};
vortex_ensure!(
data.len() == len,
"PrimitiveArray length {} does not match outer length {}",
data.len(),
len
);
let validity = crate::array::child_to_validity(&slots[0], *nullability);
if let Some(validity_len) = validity.maybe_len() {
vortex_ensure!(
validity_len == len,
"PrimitiveArray validity len {} does not match outer length {}",
validity_len,
len
);
}
Ok(())
}
fn deserialize(
&self,
dtype: &DType,
len: usize,
metadata: &[u8],
buffers: &[BufferHandle],
children: &dyn ArrayChildren,
_session: &VortexSession,
) -> VortexResult<crate::array::ArrayParts<Self>> {
if !metadata.is_empty() {
vortex_bail!(
"PrimitiveArray expects empty metadata, got {} bytes",
metadata.len()
);
}
if buffers.len() != 1 {
vortex_bail!("Expected 1 buffer, got {}", buffers.len());
}
let buffer = buffers[0].clone();
let validity = if children.is_empty() {
Validity::from(dtype.nullability())
} else if children.len() == 1 {
let validity = children.get(0, &Validity::DTYPE, len)?;
Validity::Array(validity)
} else {
vortex_bail!("Expected 0 or 1 child, got {}", children.len());
};
let ptype = PType::try_from(dtype)?;
vortex_ensure!(
buffer.is_aligned_to(Alignment::new(ptype.byte_width())),
"Misaligned buffer cannot be used to build PrimitiveArray of {ptype}"
);
if buffer.len() != ptype.byte_width() * len {
vortex_bail!(
"Buffer length {} does not match expected length {} for {}, {}",
buffer.len(),
ptype.byte_width() * len,
ptype.byte_width(),
len,
);
}
vortex_ensure!(
buffer.is_aligned_to(Alignment::new(ptype.byte_width())),
"PrimitiveArray::build: Buffer (align={}) must be aligned to {}",
buffer.alignment(),
ptype.byte_width()
);
let slots = PrimitiveData::make_slots(&validity, len);
let data = unsafe { PrimitiveData::new_unchecked_from_handle(buffer, ptype, validity) };
Ok(crate::array::ArrayParts::new(self.clone(), dtype.clone(), len, data).with_slots(slots))
}
fn slot_name(_array: ArrayView<'_, Self>, idx: usize) -> String {
SLOT_NAMES[idx].to_string()
}
fn execute(array: Array<Self>, _ctx: &mut ExecutionCtx) -> VortexResult<ExecutionResult> {
Ok(ExecutionResult::done(array))
}
fn reduce_parent(
array: ArrayView<'_, Self>,
parent: &ArrayRef,
child_idx: usize,
) -> VortexResult<Option<ArrayRef>> {
RULES.evaluate(array, parent, child_idx)
}
fn execute_parent(
array: ArrayView<'_, Self>,
parent: &ArrayRef,
child_idx: usize,
ctx: &mut ExecutionCtx,
) -> VortexResult<Option<ArrayRef>> {
PARENT_KERNELS.execute(array, parent, child_idx, ctx)
}
}
#[derive(Clone, Debug)]
pub struct Primitive;
impl Primitive {
pub const ID: ArrayId = ArrayId::new_ref("vortex.primitive");
}
#[cfg(test)]
mod tests {
use vortex_buffer::ByteBufferMut;
use vortex_buffer::buffer;
use vortex_session::registry::ReadContext;
use crate::ArrayContext;
use crate::IntoArray;
use crate::LEGACY_SESSION;
use crate::arrays::PrimitiveArray;
use crate::assert_arrays_eq;
use crate::serde::SerializeOptions;
use crate::serde::SerializedArray;
use crate::validity::Validity;
#[test]
fn test_nullable_primitive_serde_roundtrip() {
let array = PrimitiveArray::new(
buffer![1i32, 2, 3, 4],
Validity::from_iter([true, false, true, false]),
);
let dtype = array.dtype().clone();
let len = array.len();
let ctx = ArrayContext::empty();
let serialized = array
.clone()
.into_array()
.serialize(&ctx, &LEGACY_SESSION, &SerializeOptions::default())
.unwrap();
let mut concat = ByteBufferMut::empty();
for buf in serialized {
concat.extend_from_slice(buf.as_ref());
}
let parts = SerializedArray::try_from(concat.freeze()).unwrap();
let decoded = parts
.decode(
&dtype,
len,
&ReadContext::new(ctx.to_ids()),
&LEGACY_SESSION,
)
.unwrap();
assert_arrays_eq!(decoded, array);
}
}