//! Extract lines from a block of pixel bytes.
use crate::math::*;
use std::io::{Cursor};
use crate::error::{Result, UnitResult};
use smallvec::SmallVec;
use std::ops::Range;
use crate::block::{BlockIndex};
use crate::meta::attribute::ChannelList;
/// A single line of pixels.
/// Use [LineRef] or [LineRefMut] for easier type names.
#[derive(Clone, Copy, Eq, PartialEq, Debug)]
pub struct LineSlice<T> {
// TODO also store enum SampleType, as it would always be matched in every place it is used
/// Where this line is located inside the image.
pub location: LineIndex,
/// The raw bytes of the pixel line, either `&[u8]` or `&mut [u8]`.
/// Must be re-interpreted as slice of f16, f32, or u32,
/// according to the channel data type.
pub value: T,
}
/// An reference to a single line of pixels.
/// May go across the whole image or just a tile section of it.
///
/// This line contains an immutable slice that all samples will be read from.
pub type LineRef<'s> = LineSlice<&'s [u8]>;
/// A reference to a single mutable line of pixels.
/// May go across the whole image or just a tile section of it.
///
/// This line contains a mutable slice that all samples will be written to.
pub type LineRefMut<'s> = LineSlice<&'s mut [u8]>;
/// Specifies where a row of pixels lies inside an image.
/// This is a globally unique identifier which includes
/// the layer, channel index, and pixel location.
#[derive(Clone, Copy, Eq, PartialEq, Debug, Hash)]
pub struct LineIndex {
/// Index of the layer.
pub layer: usize,
/// The channel index of the layer.
pub channel: usize,
/// Index of the mip or rip level in the image.
pub level: Vec2<usize>,
/// Position of the most left pixel of the row.
pub position: Vec2<usize>,
/// The width of the line; the number of samples in this row,
/// that is, the number of f16, f32, or u32 values.
pub sample_count: usize,
}
impl LineIndex {
/// Iterates the lines of this block index in interleaved fashion:
/// For each line in this block, this iterator steps once through each channel.
/// This is how lines are stored in a pixel data block.
///
/// Does not check whether `self.layer_index`, `self.level`, `self.size` and `self.position` are valid indices.__
// TODO be sure this cannot produce incorrect data, as this is not further checked but only handled with panics
#[inline]
#[must_use]
pub fn lines_in_block(block: BlockIndex, channels: &ChannelList) -> impl Iterator<Item=(Range<usize>, LineIndex)> {
struct LineIter {
layer: usize, level: Vec2<usize>, width: usize,
end_y: usize, x: usize, channel_sizes: SmallVec<[usize; 8]>,
byte: usize, channel: usize, y: usize,
}
// FIXME what about sub sampling??
impl Iterator for LineIter {
type Item = (Range<usize>, LineIndex);
// TODO size hint?
fn next(&mut self) -> Option<Self::Item> {
if self.y < self.end_y {
// compute return value before incrementing
let byte_len = self.channel_sizes[self.channel];
let return_value = (
(self.byte .. self.byte + byte_len),
LineIndex {
channel: self.channel,
layer: self.layer,
level: self.level,
position: Vec2(self.x, self.y),
sample_count: self.width,
}
);
{ // increment indices
self.byte += byte_len;
self.channel += 1;
if self.channel == self.channel_sizes.len() {
self.channel = 0;
self.y += 1;
}
}
Some(return_value)
}
else {
None
}
}
}
let channel_line_sizes: SmallVec<[usize; 8]> = channels.list.iter()
.map(move |channel| block.pixel_size.0 * channel.sample_type.bytes_per_sample()) // FIXME is it fewer samples per tile or just fewer tiles for sampled images???
.collect();
LineIter {
layer: block.layer,
level: block.level,
width: block.pixel_size.0,
x: block.pixel_position.0,
end_y: block.pixel_position.y() + block.pixel_size.height(),
channel_sizes: channel_line_sizes,
byte: 0,
channel: 0,
y: block.pixel_position.y()
}
}
}
impl<'s> LineRefMut<'s> {
/// Writes the samples (f16, f32, u32 values) into this line value reference.
/// Use `write_samples` if there is not slice available.
#[inline]
#[must_use]
pub fn write_samples_from_slice<T: crate::io::Data>(self, slice: &[T]) -> UnitResult {
debug_assert_eq!(slice.len(), self.location.sample_count, "slice size does not match the line width");
debug_assert_eq!(self.value.len(), self.location.sample_count * T::BYTE_SIZE, "sample type size does not match line byte size");
T::write_slice(&mut Cursor::new(self.value), slice)
}
/// Iterate over all samples in this line, from left to right.
/// The supplied `get_line` function returns the sample value
/// for a given sample index within the line,
/// which starts at zero for each individual line.
/// Use `write_samples_from_slice` if you already have a slice of samples.
#[inline]
#[must_use]
pub fn write_samples<T: crate::io::Data>(self, mut get_sample: impl FnMut(usize) -> T) -> UnitResult {
debug_assert_eq!(self.value.len(), self.location.sample_count * T::BYTE_SIZE, "sample type size does not match line byte size");
let mut write = Cursor::new(self.value);
for index in 0..self.location.sample_count {
T::write(get_sample(index), &mut write)?;
}
Ok(())
}
}
impl LineRef<'_> {
/// Read the samples (f16, f32, u32 values) from this line value reference.
/// Use `read_samples` if there is not slice available.
pub fn read_samples_into_slice<T: crate::io::Data>(self, slice: &mut [T]) -> UnitResult {
debug_assert_eq!(slice.len(), self.location.sample_count, "slice size does not match the line width");
debug_assert_eq!(self.value.len(), self.location.sample_count * T::BYTE_SIZE, "sample type size does not match line byte size");
T::read_slice(&mut Cursor::new(self.value), slice)
}
/// Iterate over all samples in this line, from left to right.
/// Use `read_sample_into_slice` if you already have a slice of samples.
pub fn read_samples<T: crate::io::Data>(&self) -> impl Iterator<Item = Result<T>> + '_ {
debug_assert_eq!(self.value.len(), self.location.sample_count * T::BYTE_SIZE, "sample type size does not match line byte size");
let mut read = self.value.clone(); // FIXME deep data
(0..self.location.sample_count).map(move |_| T::read(&mut read))
}
}