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frame.rs
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frame.rs
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use crate::common::*;
use crate::error::Error;
use crate::pixel::{Format, Pixel};
use byteorder::{ByteOrder, LittleEndian};
const SWIZZLE_WIDTH: usize = 16;
const SWIZZLE_HEIGHT: usize = 8;
pub type PixelBuffer = Vec::<Pixel>;
#[derive(Debug)]
pub enum DataKind {
Indices(Vec::<u8>),
Pixels(PixelBuffer),
}
impl DataKind {
pub fn len(&self) -> usize {
match self {
DataKind::Indices(v) => v.len(),
DataKind::Pixels(v) => v.len(),
}
}
}
#[derive(Debug)]
struct Header {
total_size: u32,
palette_size: u32,
image_size: u32,
header_size: u16,
color_entry_count: u16,
paletted: u8,
mipmap_count: u8,
clut_format: u8,
bpp: u8,
width: usize,
height: usize,
gs_regs: u32,
gs_tex_clut: u32,
gs_tex_0: [u8;8],
gs_tex_1: [u8;8],
user_data: Vec::<u8>,
}
impl Header {
pub fn read(buffer: &[u8], offset: &mut usize) -> Result<Header, Error> {
let mut load_part = |size| { get_slice(&buffer, offset, size) };
let mut result = Header {
total_size: LittleEndian::read_u32(load_part(4)),
palette_size: LittleEndian::read_u32(load_part(4)),
image_size: LittleEndian::read_u32(load_part(4)),
header_size: LittleEndian::read_u16(load_part(2)),
color_entry_count: LittleEndian::read_u16(load_part(2)),
paletted: load_part(1)[0],
mipmap_count: load_part(1)[0],
clut_format: load_part(1)[0],
bpp: Header::find_bpp(load_part(1)[0])?,
width: LittleEndian::read_u16(load_part(2)) as usize,
height: LittleEndian::read_u16(load_part(2)) as usize,
gs_tex_0: clone_into_array(load_part(8)),
gs_tex_1: clone_into_array(load_part(8)),
gs_regs: LittleEndian::read_u32(load_part(4)),
gs_tex_clut: LittleEndian::read_u32(load_part(4)),
user_data: Vec::new(),
};
let user_data_size = result.header_size as usize - 48;
if user_data_size > 0 {
result.user_data = load_part(user_data_size).to_vec();
}
if result.palette_size > 0 && result.bpp > 8 {
Err(Error::TrueColorAndPaletteFound)
} else {
Ok(result)
}
}
fn find_bpp(v: u8) -> Result<u8, Error> {
match v {
1 => Ok(16),
2 => Ok(24),
3 => Ok(32),
4 => Ok(4),
5 => Ok(8),
n => Err(Error::InvalidBppFormat(n)),
}
}
pub fn is_linear_palette(&self) -> bool {
self.clut_format & 0x80 != 0
}
pub fn color_size(&self) -> usize {
if self.bpp > 8 {
(self.bpp / 8) as usize
} else {
(self.clut_format & 0x07) as usize + 1
}
}
pub fn pixel_format(&self) -> Result<Format, Error> {
match self.bpp {
4 => Ok(Format::Indexed),
8 => Ok(Format::Indexed),
16 => Ok(Format::Abgr1555),
24 => Ok(Format::Rgb888),
32 => Ok(Format::Rgba8888),
n => Err(Error::InvalidBpp(n)),
}
}
}
#[derive(Debug)]
pub struct Frame {
header: Header,
data: DataKind,
palettes: Vec::<PixelBuffer>,
}
impl Frame {
pub fn read(buffer: &[u8], offset: &mut usize) -> Result<Frame, Error> {
let header = Header::read(buffer, offset)?;
let data = Frame::read_data(buffer, offset, &header)?;
let palettes= Frame::read_palettes(buffer, offset, &header)?;
Ok(Frame { header, data, palettes })
}
fn read_data(buffer: &[u8], offset: &mut usize, header: &Header) -> Result<DataKind, Error> {
let pixel_size = header.bpp as usize / 8;
let size = header.image_size as usize;
let slice = get_slice(buffer, offset, size);
let data = if header.bpp == 4 {
let mut result = Vec::with_capacity(slice.len() * 2);
for index_pair in slice {
result.push(*index_pair & 0xF0 >> 4);
result.push(*index_pair & 0xF);
}
result
} else {
slice.to_vec()
};
if header.palette_size > 0 {
let raw = Frame::unswizzle(&data.to_vec(), header);
Ok(DataKind::Indices(raw))
} else {
let colors = Frame::read_colors(&data, pixel_size)?;
let raw = Frame::unswizzle(&colors, header);
Ok(DataKind::Pixels(raw))
}
}
fn read_palettes(buffer: &[u8], offset: &mut usize, header: &Header) -> Result<Vec<PixelBuffer>, Error> {
let total_size = header.palette_size as usize;
let slice = get_slice(buffer, offset, total_size);
let size = header.color_entry_count as usize * header.color_size();
let count = total_size / size;
let color_size = header.color_size();
let mut result = Vec::with_capacity(count);
for i in 0..count {
let start_index = size * i;
let end_index = start_index + size;
let data = &slice[start_index..end_index];
let mut palette = Frame::read_colors(data, color_size)?;
if !header.is_linear_palette() && header.bpp == 8 {
Frame::linearize_palette(&mut palette);
}
result.push(palette);
}
Ok(result)
}
fn read_colors(buffer: &[u8], color_size: usize) -> Result<PixelBuffer, Error> {
let mut offset = 0usize;
let mut result = Vec::new();
for _ in (0..buffer.len()).step_by(color_size) {
let slice = get_slice(buffer, &mut offset, color_size);
let pixel = Pixel::from_buf(slice)?;
result.push(pixel)
}
Ok(result)
}
fn linearize_palette(palette: &mut PixelBuffer) {
const COLOR_COUNT: usize = 8;
const BLOCK_COUNT: usize = 2;
const STRIPE_COUNT: usize = 2;
let mut i = 0usize;
let part_count = palette.len() / 32;
let original = palette.clone();
for part in 0..part_count {
for block in 0..BLOCK_COUNT {
for stripe in 0..STRIPE_COUNT {
for color in 0..COLOR_COUNT {
let i1 = part * COLOR_COUNT * STRIPE_COUNT * BLOCK_COUNT;
let i2 = block * COLOR_COUNT;
let i3 = stripe * STRIPE_COUNT * COLOR_COUNT;
palette[i] = original[i1 + i2 + i3 + color];
i += 1;
}
}
}
}
}
fn unswizzle<T: Default + Copy>(buffer: &Vec::<T>, header: &Header) -> Vec::<T> {
let mut i = 0usize;
let mut result = vec![Default::default(); buffer.len()];
for y in (0..header.height).step_by(SWIZZLE_HEIGHT) {
for x in (0..header.width).step_by(SWIZZLE_WIDTH) {
for tile_y in y..(y + SWIZZLE_HEIGHT) {
for tile_x in x..(x + SWIZZLE_WIDTH) {
if tile_x < header.width && tile_y < header.height {
let index = tile_y * header.width + tile_x;
result[index] = buffer[i];
}
i += 1;
}
}
}
}
result
}
pub fn has_mipmaps(&self) -> bool {
self.header.mipmap_count > 1
}
pub fn width(&self) -> usize {
self.header.width as usize
}
pub fn height(&self) -> usize {
self.header.height as usize
}
pub fn format(&self) -> Result<Format, Error> {
self.header.pixel_format()
}
pub fn data(&self) -> &DataKind {
&self.data
}
pub fn get_pixels(&self) -> PixelBuffer {
let palette = &self.palettes[0];
match &self.data {
DataKind::Indices(v) => {
let mut result = Vec::with_capacity(v.len());
for index in v {
result.push(palette[*index as usize]);
}
result
},
DataKind::Pixels(v) => v.to_vec(),
}
}
pub fn to_raw(&self, color_key: Option<Pixel>) -> Vec::<u8> {
let pixels = self.get_pixels();
let mut result = Vec::with_capacity(pixels.len() * 4);
for pixel in pixels {
let alpha = if let Some(v) = color_key {
if v != pixel { pixel.a() } else { 0 }
} else {
pixel.a()
};
result.push(pixel.r());
result.push(pixel.g());
result.push(pixel.b());
result.push(alpha);
}
result
}
}