array_object/convert/
into_complex.rsuse crate::adaptor::*;
use crate::error::ArrayObjectError;
use crate::storage::*;
use num_complex::Complex;
macro_rules! into_complex {
($($ty:tt),*) => {
$(
impl TryFrom<ArrayObject> for Pair<$ty> {
type Error = ArrayObjectError;
fn try_from(mut val: ArrayObject) -> Result<Self, Self::Error> {
if !val.shape.is_empty() || val.datatype != DataType::Complex {
return Err(ArrayObjectError::WrongDataType(val.datatype, val.shape.len()));
}
match val.data.len() / 2 {
4 => {
let data_im = val.data.split_off(4);
let re = f32::from_le_bytes(val.data.try_into().unwrap()) as $ty;
let im = f32::from_le_bytes(data_im.try_into().unwrap()) as $ty;
Ok(Pair(re, im))
}
8 => {
#[cfg(not(feature = "allow_float_down_convert"))]
if size_of::<$ty>() < 8 {
return Err(ArrayObjectError::LossyConversion);
}
let data_im = val.data.split_off(8);
let re = f64::from_le_bytes(val.data.try_into().unwrap()) as $ty;
let im = f64::from_le_bytes(data_im.try_into().unwrap()) as $ty;
Ok(Pair(re, im))
}
_ => {panic!();}
}
}
}
impl TryFrom<ArrayObject> for Complex<$ty> {
type Error = ArrayObjectError;
fn try_from(val: ArrayObject) -> Result<Self, Self::Error> {
let Pair(re, im) = val.try_into()?;
Ok(Complex::new(re, im))
}
}
impl TryFrom<ArrayObject> for VecShape<Pair<$ty>> {
type Error = ArrayObjectError;
fn try_from(val: ArrayObject) -> Result<Self, Self::Error> {
if val.shape.is_empty() || val.datatype != DataType::Complex {
return Err(ArrayObjectError::WrongDataType(val.datatype, val.shape.len()));
}
let len = val.len();
if len == 0 {
return Ok(VecShape(vec![], val.shape));
}
match val.data.len() / (2 * len) {
4 => {
let data = val.data.chunks(8).map(|b| {
let mut iter = b.chunks(4);
let re = f32::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty;
let im = f32::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty;
Pair(re, im)
}).collect();
Ok(VecShape(data, val.shape))
}
8 => {
#[cfg(not(feature = "allow_float_down_convert"))]
if size_of::<$ty>() < 8 {
return Err(ArrayObjectError::LossyConversion);
}
let data = val.data.chunks(16).map(|b| {
let mut iter = b.chunks(8);
let re = f64::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty;
let im = f64::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty;
Pair(re, im)
}).collect();
Ok(VecShape(data, val.shape))
}
_ => {panic!();}
}
}
}
impl TryFrom<ArrayObject> for VecShape<Complex<$ty>> {
type Error = ArrayObjectError;
fn try_from(val: ArrayObject) -> Result<Self, Self::Error> {
if val.shape.is_empty() || val.datatype != DataType::Complex {
return Err(ArrayObjectError::WrongDataType(val.datatype, val.shape.len()));
}
let len = val.len();
if len == 0 {
return Ok(VecShape(vec![], val.shape));
}
match val.data.len() / (2 * len) {
4 => {
let data = val.data.chunks(8).map(|b| {
let mut iter = b.chunks(4);
let re = f32::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty;
let im = f32::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty;
Complex::<$ty>::new(re, im)
}).collect();
Ok(VecShape(data, val.shape))
}
8 => {
#[cfg(not(feature = "allow_float_down_convert"))]
if size_of::<$ty>() < 8 {
return Err(ArrayObjectError::LossyConversion);
}
let data = val.data.chunks(16).map(|b| {
let mut iter = b.chunks(8);
let re = f64::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty;
let im = f64::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty;
Complex::<$ty>::new(re, im)
}).collect();
Ok(VecShape(data, val.shape))
}
_ => {panic!();}
}
}
}
impl TryFrom<ArrayObject> for VecVecShape<$ty> {
type Error = ArrayObjectError;
fn try_from(val: ArrayObject) -> Result<Self, Self::Error> {
if val.shape.is_empty() || val.datatype != DataType::Complex {
return Err(ArrayObjectError::WrongDataType(val.datatype, val.shape.len()));
}
let len = val.len();
if len == 0 {
return Ok(VecVecShape(vec![], vec![], val.shape));
}
let mut re = Vec::<$ty>::with_capacity(len * 2);
let mut im = Vec::<$ty>::with_capacity(len * 2);
match val.data.len() / (2 * len) {
4 => {
for b in val.data.chunks(8) {
let mut iter = b.chunks(4);
re.push(f32::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty);
im.push(f32::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty);
}
}
8 => {
#[cfg(not(feature = "allow_float_down_convert"))]
if size_of::<$ty>() < 8 {
return Err(ArrayObjectError::LossyConversion);
}
for b in val.data.chunks(16) {
let mut iter = b.chunks(8);
re.push(f64::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty);
im.push(f64::from_le_bytes(iter.next().unwrap().to_vec().try_into().unwrap()) as $ty);
}
}
_ => {panic!();}
}
Ok(VecVecShape(re, im, val.shape))
}
}
impl TryFrom<ArrayObject> for Vec<Complex<$ty>> {
type Error = ArrayObjectError;
fn try_from(val: ArrayObject) -> Result<Self, Self::Error> {
if val.shape.len() != 1 {
return Err(ArrayObjectError::WrongDataType(val.datatype, val.shape.len()));
}
let VecShape::<Complex<$ty>>(data, _) = val.try_into()?;
Ok(data)
}
}
impl<const N: usize> TryFrom<ArrayObject> for [Complex<$ty>; N] {
type Error = ArrayObjectError;
fn try_from(val: ArrayObject) -> Result<Self, Self::Error> {
if val.len() != N {
return Err(ArrayObjectError::WrongDataType(val.datatype, val.shape.len()));
}
let data: Vec<Complex<$ty>> = val.try_into()?;
Ok(data.try_into().unwrap())
}
}
)*
};
}
into_complex!(f32, f64);