+//! Audio and image sample format definitions.
+//!
+//! NihAV does not have a fixed list of supported formats but rather accepts format definitions both for audio and video.
+//! In result exotic formats like YUV410+alpha plane that is used by Indeo 4 are supported without any additional case handing.
+//! Some common format definitions are provided as constants for convenience.
use std::str::FromStr;
use std::string::*;
use std::fmt;
+/// Generic format parsing error.
+#[derive(Clone,Copy,Debug,PartialEq)]
+pub struct FormatParseError {}
+
+/// Audio format definition.
+///
+/// The structure describes how audio samples are stored and what characteristics they have.
#[derive(Debug,Copy,Clone,PartialEq)]
pub struct NASoniton {
- bits: u8,
- be: bool,
- packed: bool,
- planar: bool,
- float: bool,
- signed: bool,
+ /// Bits per sample.
+ pub bits: u8,
+ /// Audio format is big-endian.
+ pub be: bool,
+ /// Audio samples are packed (e.g. 20-bit audio samples).
+ pub packed: bool,
+ /// Audio data is stored in planar format instead of interleaving samples for different channels.
+ pub planar: bool,
+ /// Audio data is in floating point format.
+ pub float: bool,
+ /// Audio data is signed (usually only 8-bit audio is unsigned).
+ pub signed: bool,
}
+/// Flag for specifying that audio format is big-endian in `NASoniton::`[`new`]`()`. Related to [`be`] field of `NASoniton`.
+///
+/// [`new`]: ./struct.NASoniton.html#method.new
+/// [`be`]: ./struct.NASoniton.html#structfield.be
pub const SONITON_FLAG_BE :u32 = 0x01;
+/// Flag for specifying that audio format has packed samples in `NASoniton::`[`new`]`()`. Related to [`packed`] field of `NASoniton`.
+///
+/// [`new`]: ./struct.NASoniton.html#method.new
+/// [`packed`]: ./struct.NASoniton.html#structfield.packed
pub const SONITON_FLAG_PACKED :u32 = 0x02;
+/// Flag for specifying that audio data is stored as planar in `NASoniton::`[`new`]`()`. Related to [`planar`] field of `NASoniton`.
+///
+/// [`new`]: ./struct.NASoniton.html#method.new
+/// [`planar`]: ./struct.NASoniton.html#structfield.planar
pub const SONITON_FLAG_PLANAR :u32 = 0x04;
+/// Flag for specifying that audio samples are in floating point format in `NASoniton::`[`new`]`()`. Related to [`float`] field of `NASoniton`.
+///
+/// [`new`]: ./struct.NASoniton.html#method.new
+/// [`float`]: ./struct.NASoniton.html#structfield.float
pub const SONITON_FLAG_FLOAT :u32 = 0x08;
+/// Flag for specifying that audio format is signed in `NASoniton::`[`new`]`()`. Related to [`signed`] field of `NASoniton`.
+///
+/// [`new`]: ./struct.NASoniton.html#method.new
+/// [`signed`]: ./struct.NASoniton.html#structfield.signed
pub const SONITON_FLAG_SIGNED :u32 = 0x10;
+/// Predefined format for interleaved 8-bit unsigned audio.
pub const SND_U8_FORMAT: NASoniton = NASoniton { bits: 8, be: false, packed: false, planar: false, float: false, signed: false };
+/// Predefined format for interleaved 16-bit signed audio.
pub const SND_S16_FORMAT: NASoniton = NASoniton { bits: 16, be: false, packed: false, planar: false, float: false, signed: true };
+/// Predefined format for planar 16-bit signed audio.
pub const SND_S16P_FORMAT: NASoniton = NASoniton { bits: 16, be: false, packed: false, planar: true, float: false, signed: true };
+/// Predefined format for planar 32-bit signed audio.
+pub const SND_S32P_FORMAT: NASoniton = NASoniton { bits: 32, be: false, packed: false, planar: true, float: false, signed: true };
+/// Predefined format for planar 32-bit floating point audio.
pub const SND_F32P_FORMAT: NASoniton = NASoniton { bits: 32, be: false, packed: false, planar: true, float: true, signed: true };
impl NASoniton {
+ /// Constructs a new audio format definition using flags like [`SONITON_FLAG_BE`].
+ ///
+ /// [`SONITON_FLAG_BE`]: ./constant.SONITON_FLAG_BE.html
pub fn new(bits: u8, flags: u32) -> Self {
let is_be = (flags & SONITON_FLAG_BE) != 0;
let is_pk = (flags & SONITON_FLAG_PACKED) != 0;
NASoniton { bits, be: is_be, packed: is_pk, planar: is_pl, float: is_fl, signed: is_sg }
}
+ /// Returns the number of bits per sample.
pub fn get_bits(self) -> u8 { self.bits }
+ /// Reports whether the format is big-endian.
pub fn is_be(self) -> bool { self.be }
+ /// Reports whether the format has packed samples.
pub fn is_packed(self) -> bool { self.packed }
+ /// Reports whether audio data is planar instead of interleaved.
pub fn is_planar(self) -> bool { self.planar }
+ /// Reports whether audio samples are in floating point format.
pub fn is_float(self) -> bool { self.float }
+ /// Reports whether audio samples are signed.
pub fn is_signed(self) -> bool { self.signed }
+ /// Returns the amount of bytes needed to store the audio of requested length (in samples).
pub fn get_audio_size(self, length: u64) -> usize {
if self.packed {
((length * u64::from(self.bits) + 7) >> 3) as usize
(length * u64::from((self.bits + 7) >> 3)) as usize
}
}
+
+ /// Returns soniton description as a short string.
+ pub fn to_short_string(self) -> String {
+ let ltype = if self.float { 'f' } else if self.signed { 's' } else { 'u' };
+ let endianness = if self.bits == 8 { "" } else if self.be { "be" } else { "le" };
+ let planar = if self.planar { "p" } else { "" };
+ let packed = if self.packed { "x" } else { "" };
+ format!("{}{}{}{}{}", ltype, self.bits, endianness, planar, packed)
+ }
}
impl fmt::Display for NASoniton {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let fmt = if self.float { "float" } else if self.signed { "int" } else { "uint" };
let end = if self.be { "BE" } else { "LE" };
- write!(f, "({} bps, {} planar: {} packed: {} {})", self.bits, end, self.packed, self.planar, fmt)
+ write!(f, "({} bps, {} planar: {} packed: {} {})", self.bits, end, self.planar, self.packed, fmt)
+ }
+}
+
+impl FromStr for NASoniton {
+ type Err = FormatParseError;
+
+ fn from_str(s: &str) -> Result<Self, Self::Err> {
+ match s {
+ "u8" => Ok(NASoniton { bits: 8, be: true, packed: false, planar: false, float: false, signed: false }),
+ "s16be" => Ok(NASoniton { bits: 16, be: true, packed: false, planar: false, float: false, signed: true }),
+ "s16le" => Ok(NASoniton { bits: 16, be: false, packed: false, planar: false, float: false, signed: true }),
+ "s24be" => Ok(NASoniton { bits: 24, be: true, packed: false, planar: false, float: false, signed: true }),
+ "s24le" => Ok(NASoniton { bits: 24, be: false, packed: false, planar: false, float: false, signed: true }),
+ "s32be" => Ok(NASoniton { bits: 32, be: true, packed: false, planar: false, float: false, signed: true }),
+ "s32le" => Ok(NASoniton { bits: 32, be: false, packed: false, planar: false, float: false, signed: true }),
+ "f32be" => Ok(NASoniton { bits: 32, be: true, packed: false, planar: false, float: true, signed: true }),
+ "f32le" => Ok(NASoniton { bits: 32, be: false, packed: false, planar: false, float: true, signed: true }),
+ _ => Err(FormatParseError{}),
+ }
}
}
+/// Known channel types.
#[derive(Debug,Clone,Copy,PartialEq)]
pub enum NAChannelType {
C, L, R, Cs, Ls, Rs, Lss, Rss, LFE, Lc, Rc, Lh, Rh, Ch, LFE2, Lw, Rw, Ov, Lhs, Rhs, Chs, Ll, Rl, Cl, Lt, Rt, Lo, Ro
}
impl NAChannelType {
+ /// Reports whether this is some center channel.
pub fn is_center(self) -> bool {
- match self {
- NAChannelType::C => true, NAChannelType::Ch => true,
- NAChannelType::Cl => true, NAChannelType::Ov => true,
- NAChannelType::LFE => true, NAChannelType::LFE2 => true,
- NAChannelType::Cs => true, NAChannelType::Chs => true,
- _ => false,
- }
+ matches!(self,
+ NAChannelType::C | NAChannelType::Ch |
+ NAChannelType::Cl | NAChannelType::Ov |
+ NAChannelType::LFE | NAChannelType::LFE2 |
+ NAChannelType::Cs | NAChannelType::Chs)
}
+ /// Reports whether this is some left channel.
pub fn is_left(self) -> bool {
- match self {
- NAChannelType::L => true, NAChannelType::Ls => true,
- NAChannelType::Lss => true, NAChannelType::Lc => true,
- NAChannelType::Lh => true, NAChannelType::Lw => true,
- NAChannelType::Lhs => true, NAChannelType::Ll => true,
- NAChannelType::Lt => true, NAChannelType::Lo => true,
- _ => false,
- }
+ matches!(self,
+ NAChannelType::L | NAChannelType::Ls |
+ NAChannelType::Lss | NAChannelType::Lc |
+ NAChannelType::Lh | NAChannelType::Lw |
+ NAChannelType::Lhs | NAChannelType::Ll |
+ NAChannelType::Lt | NAChannelType::Lo)
}
+ /// Reports whether this is some right channel.
pub fn is_right(self) -> bool {
- match self {
- NAChannelType::R => true, NAChannelType::Rs => true,
- NAChannelType::Rss => true, NAChannelType::Rc => true,
- NAChannelType::Rh => true, NAChannelType::Rw => true,
- NAChannelType::Rhs => true, NAChannelType::Rl => true,
- NAChannelType::Rt => true, NAChannelType::Ro => true,
- _ => false,
- }
+ matches!(self,
+ NAChannelType::R | NAChannelType::Rs |
+ NAChannelType::Rss | NAChannelType::Rc |
+ NAChannelType::Rh | NAChannelType::Rw |
+ NAChannelType::Rhs | NAChannelType::Rl |
+ NAChannelType::Rt | NAChannelType::Ro)
}
}
-#[derive(Clone,Copy,Debug,PartialEq)]
-pub struct ChannelParseError {}
-
impl FromStr for NAChannelType {
- type Err = ChannelParseError;
+ type Err = FormatParseError;
fn from_str(s: &str) -> Result<Self, Self::Err> {
match s {
"Rt" => Ok(NAChannelType::Rt),
"Lo" => Ok(NAChannelType::Lo),
"Ro" => Ok(NAChannelType::Ro),
- _ => Err(ChannelParseError{}),
+ _ => Err(FormatParseError{}),
}
}
}
}
}
+/// Channel map.
+///
+/// This is essentially an ordered sequence of channels.
#[derive(Clone,Default)]
pub struct NAChannelMap {
ids: Vec<NAChannelType>,
];
impl NAChannelMap {
+ /// Constructs a new `NAChannelMap` instance.
pub fn new() -> Self { NAChannelMap { ids: Vec::new() } }
+ /// Adds a new channel to the map.
pub fn add_channel(&mut self, ch: NAChannelType) {
self.ids.push(ch);
}
+ /// Adds several channels to the map at once.
pub fn add_channels(&mut self, chs: &[NAChannelType]) {
for e in chs.iter() {
self.ids.push(*e);
}
}
+ /// Returns the total number of channels.
pub fn num_channels(&self) -> usize {
self.ids.len()
}
+ /// Reports channel type for a requested index.
pub fn get_channel(&self, idx: usize) -> NAChannelType {
self.ids[idx]
}
+ /// Tries to find position of the channel with requested type.
pub fn find_channel_id(&self, t: NAChannelType) -> Option<u8> {
for i in 0..self.ids.len() {
if self.ids[i] as i32 == t as i32 { return Some(i as u8); }
}
None
}
+ /// Creates a new `NAChannelMap` using the channel mapping flags from WAVE format.
pub fn from_ms_mapping(chmap: u32) -> Self {
let mut cm = NAChannelMap::new();
for (i, ch) in MS_CHANNEL_MAP.iter().enumerate() {
}
impl FromStr for NAChannelMap {
- type Err = ChannelParseError;
+ type Err = FormatParseError;
fn from_str(s: &str) -> Result<Self, Self::Err> {
let mut chm = NAChannelMap::new();
}
}
+/// A list of RGB colour model variants.
#[derive(Debug,Clone,Copy,PartialEq)]
pub enum RGBSubmodel {
RGB,
}
}
+/// A list of YUV colour model variants.
#[derive(Debug,Clone,Copy,PartialEq)]
pub enum YUVSubmodel {
YCbCr,
+ /// NTSC variant.
YIQ,
+ /// The YUV variant used by JPEG.
YUVJ,
}
}
}
+/// A list of known colour models.
#[derive(Debug, Clone,Copy,PartialEq)]
pub enum ColorModel {
RGB(RGBSubmodel),
}
impl ColorModel {
+ /// Returns the number of colour model components.
+ ///
+ /// The actual image may have more components e.g. alpha component.
pub fn get_default_components(self) -> usize {
match self {
ColorModel::CMYK => 4,
_ => 3,
}
}
+ /// Reports whether the current colour model is RGB.
pub fn is_rgb(self) -> bool {
- match self {
- ColorModel::RGB(_) => true,
- _ => false,
- }
+ matches!(self, ColorModel::RGB(_))
}
+ /// Reports whether the current colour model is YUV.
pub fn is_yuv(self) -> bool {
- match self {
- ColorModel::YUV(_) => true,
- _ => false,
- }
+ matches!(self, ColorModel::YUV(_))
}
+ /// Returns short name for the current colour mode.
pub fn get_short_name(self) -> &'static str {
match self {
ColorModel::RGB(_) => "rgb",
impl fmt::Display for ColorModel {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let name = match *self {
- ColorModel::RGB(fmt) => format!("RGB({})", fmt).to_string(),
- ColorModel::YUV(fmt) => format!("YUV({})", fmt).to_string(),
+ ColorModel::RGB(fmt) => format!("RGB({})", fmt),
+ ColorModel::YUV(fmt) => format!("YUV({})", fmt),
ColorModel::CMYK => "CMYK".to_string(),
ColorModel::HSV => "HSV".to_string(),
ColorModel::LAB => "LAB".to_string(),
}
}
+/// Single colourspace component definition.
+///
+/// This structure defines how components of a colourspace are subsampled and where and how they are stored.
#[derive(Clone,Copy,PartialEq)]
pub struct NAPixelChromaton {
+ /// Horizontal subsampling in power of two (e.g. `0` = no subsampling, `1` = only every second value is stored).
pub h_ss: u8,
+ /// Vertial subsampling in power of two (e.g. `0` = no subsampling, `1` = only every second value is stored).
pub v_ss: u8,
+ /// A flag to signal that component is packed.
pub packed: bool,
+ /// Bit depth of current component.
pub depth: u8,
+ /// Shift for packed components.
pub shift: u8,
+ /// Component offset for byte-packed components.
pub comp_offs: u8,
+ /// The distance to the next packed element in bytes.
pub next_elem: u8,
}
+/// Flag for specifying that image data is stored big-endian in `NAPixelFormaton::`[`new`]`()`. Related to its [`be`] field.
+///
+/// [`new`]: ./struct.NAPixelFormaton.html#method.new
+/// [`be`]: ./struct.NAPixelFormaton.html#structfield.new
pub const FORMATON_FLAG_BE :u32 = 0x01;
+/// Flag for specifying that image data has alpha plane in `NAPixelFormaton::`[`new`]`()`. Related to its [`alpha`] field.
+///
+/// [`new`]: ./struct.NAPixelFormaton.html#method.new
+/// [`alpha`]: ./struct.NAPixelFormaton.html#structfield.alpha
pub const FORMATON_FLAG_ALPHA :u32 = 0x02;
+/// Flag for specifying that image data is stored in paletted form for `NAPixelFormaton::`[`new`]`()`. Related to its [`palette`] field.
+///
+/// [`new`]: ./struct.NAPixelFormaton.html#method.new
+/// [`palette`]: ./struct.NAPixelFormaton.html#structfield.palette
pub const FORMATON_FLAG_PALETTE :u32 = 0x04;
+/// The current limit on number of components in image colourspace model (including alpha component).
pub const MAX_CHROMATONS: usize = 5;
+/// Image colourspace representation.
+///
+/// This structure includes both definitions for each component and some common definitions.
+/// For example the format can be paletted and then components describe the palette storage format while actual data is 8-bit palette indices.
#[derive(Clone,Copy,PartialEq)]
pub struct NAPixelFormaton {
+ /// Image colour model.
pub model: ColorModel,
+ /// Actual number of components present.
pub components: u8,
+ /// Format definition for each component.
pub comp_info: [Option<NAPixelChromaton>; MAX_CHROMATONS],
+ /// Single pixel size for packed formats.
pub elem_size: u8,
+ /// A flag signalling that data is stored as big-endian.
pub be: bool,
+ /// A flag signalling that image has alpha component.
pub alpha: bool,
+ /// A flag signalling that data is paletted.
+ ///
+ /// This means that image data is stored as 8-bit indices (in the first image component) for the palette stored as second component of the image and actual palette format is described in this structure.
pub palette: bool,
}
});
}
+/// Predefined format for planar 8-bit YUV with 4:2:0 subsampling.
pub const YUV420_FORMAT: NAPixelFormaton = NAPixelFormaton { model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 3,
comp_info: [
chromaton!(0, 0, false, 8, 0, 0, 1),
None, None],
elem_size: 0, be: false, alpha: false, palette: false };
+/// Predefined format for planar 8-bit YUV with 4:1:0 subsampling.
pub const YUV410_FORMAT: NAPixelFormaton = NAPixelFormaton { model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 3,
comp_info: [
chromaton!(0, 0, false, 8, 0, 0, 1),
chromaton!(yuv8; 2, 2, 2),
None, None],
elem_size: 0, be: false, alpha: false, palette: false };
+/// Predefined format for planar 8-bit YUV with 4:1:0 subsampling and alpha component.
pub const YUVA410_FORMAT: NAPixelFormaton = NAPixelFormaton { model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 4,
comp_info: [
chromaton!(0, 0, false, 8, 0, 0, 1),
None],
elem_size: 0, be: false, alpha: true, palette: false };
+/// Predefined format with RGB24 palette.
pub const PAL8_FORMAT: NAPixelFormaton = NAPixelFormaton { model: ColorModel::RGB(RGBSubmodel::RGB), components: 3,
comp_info: [
chromaton!(pal8; 0),
None, None],
elem_size: 3, be: false, alpha: false, palette: true };
+/// Predefined format for RGB565 packed video.
pub const RGB565_FORMAT: NAPixelFormaton = NAPixelFormaton { model: ColorModel::RGB(RGBSubmodel::RGB), components: 3,
comp_info: [
chromaton!(packrgb; 5, 11, 0, 2),
None, None],
elem_size: 2, be: false, alpha: false, palette: false };
+/// Predefined format for RGB24.
pub const RGB24_FORMAT: NAPixelFormaton = NAPixelFormaton { model: ColorModel::RGB(RGBSubmodel::RGB), components: 3,
comp_info: [
chromaton!(packrgb; 8, 0, 0, 3),
elem_size: 3, be: false, alpha: false, palette: false };
impl NAPixelChromaton {
+ /// Constructs a new `NAPixelChromaton` instance.
pub fn new(h_ss: u8, v_ss: u8, packed: bool, depth: u8, shift: u8, comp_offs: u8, next_elem: u8) -> Self {
Self { h_ss, v_ss, packed, depth, shift, comp_offs, next_elem }
}
+ /// Returns subsampling for the current component.
pub fn get_subsampling(self) -> (u8, u8) { (self.h_ss, self.v_ss) }
+ /// Reports whether current component is packed.
pub fn is_packed(self) -> bool { self.packed }
+ /// Returns bit depth of current component.
pub fn get_depth(self) -> u8 { self.depth }
+ /// Returns bit shift for packed component.
pub fn get_shift(self) -> u8 { self.shift }
+ /// Returns byte offset for packed component.
pub fn get_offset(self) -> u8 { self.comp_offs }
+ /// Returns byte offset to the next element of current packed component.
pub fn get_step(self) -> u8 { self.next_elem }
+ /// Calculates the width for current component from general image width.
pub fn get_width(self, width: usize) -> usize {
(width + ((1 << self.h_ss) - 1)) >> self.h_ss
}
+ /// Calculates the height for current component from general image height.
pub fn get_height(self, height: usize) -> usize {
(height + ((1 << self.v_ss) - 1)) >> self.v_ss
}
+ /// Calculates the minimal stride for current component from general image width.
pub fn get_linesize(self, width: usize) -> usize {
let d = self.depth as usize;
if self.packed {
self.get_width(width)
}
}
+ /// Calculates the required image size in pixels for current component from general image width.
pub fn get_data_size(self, width: usize, height: usize) -> usize {
let nh = (height + ((1 << self.v_ss) - 1)) >> self.v_ss;
self.get_linesize(width) * nh
}
impl NAPixelFormaton {
+ /// Constructs a new instance of `NAPixelFormaton`.
pub fn new(model: ColorModel,
comp1: Option<NAPixelChromaton>,
comp2: Option<NAPixelChromaton>,
be, alpha, palette }
}
+ /// Returns current colour model.
pub fn get_model(&self) -> ColorModel { self.model }
+ /// Returns the number of components.
pub fn get_num_comp(&self) -> usize { self.components as usize }
+ /// Returns selected component information.
pub fn get_chromaton(&self, idx: usize) -> Option<NAPixelChromaton> {
if idx < self.comp_info.len() { return self.comp_info[idx]; }
None
}
+ /// Reports whether the packing format is big-endian.
pub fn is_be(self) -> bool { self.be }
+ /// Reports whether colourspace has alpha component.
pub fn has_alpha(self) -> bool { self.alpha }
+ /// Reports whether this is paletted format.
pub fn is_paletted(self) -> bool { self.palette }
+ /// Returns single packed pixel size.
pub fn get_elem_size(self) -> u8 { self.elem_size }
+ /// Reports whether the format is not packed.
pub fn is_unpacked(&self) -> bool {
if self.palette { return false; }
for chr in self.comp_info.iter() {
}
true
}
+ /// Returns the maximum component bit depth.
pub fn get_max_depth(&self) -> u8 {
let mut mdepth = 0;
for chr in self.comp_info.iter() {
}
mdepth
}
+ /// Returns the total amount of bits needed for components.
+ pub fn get_total_depth(&self) -> u8 {
+ let mut depth = 0;
+ for chr in self.comp_info.iter() {
+ if let Some(ref chromaton) = chr {
+ depth += chromaton.depth;
+ }
+ }
+ depth
+ }
+ /// Returns the maximum component subsampling.
pub fn get_max_subsampling(&self) -> u8 {
let mut ssamp = 0;
for chr in self.comp_info.iter() {
}
ssamp
}
+ #[allow(clippy::cognitive_complexity)]
+ /// Returns a short string description of the format if possible.
+ pub fn to_short_string(&self) -> Option<String> {
+ match self.model {
+ ColorModel::RGB(_) => {
+ if self.is_paletted() {
+ if *self == PAL8_FORMAT {
+ return Some("pal8".to_string());
+ } else {
+ return None;
+ }
+ }
+ let mut name = [b'z'; 4];
+ let planar = self.is_unpacked();
+
+ let mut start_off = 0;
+ let mut start_shift = 0;
+ let mut use_shift = true;
+ for comp in self.comp_info.iter() {
+ if let Some(comp) = comp {
+ start_off = start_off.min(comp.comp_offs);
+ start_shift = start_shift.min(comp.shift);
+ if comp.comp_offs != 0 { use_shift = false; }
+ }
+ }
+ for component in 0..(self.components as usize) {
+ for (comp, cname) in self.comp_info.iter().zip(b"rgba".iter()) {
+ if let Some(comp) = comp {
+ if use_shift {
+ if comp.shift == start_shift {
+ name[component] = *cname;
+ start_shift += comp.depth;
+ }
+ } else if comp.comp_offs == start_off {
+ name[component] = *cname;
+ if planar {
+ start_off += 1;
+ } else {
+ start_off += (comp.depth + 7) / 8;
+ }
+ }
+ }
+ }
+ }
+
+ for (comp, cname) in self.comp_info.iter().zip(b"rgba".iter()) {
+ if let Some(comp) = comp {
+ name[comp.comp_offs as usize] = *cname;
+ } else {
+ break;
+ }
+ }
+ let mut name = String::from_utf8(name[..self.components as usize].to_vec()).unwrap();
+ let depth = self.get_total_depth();
+ if depth == 15 || depth == 16 {
+ for c in self.comp_info.iter() {
+ if let Some(comp) = c {
+ name.push((b'0' + comp.depth) as char);
+ } else {
+ break;
+ }
+ }
+ name += if self.be { "be" } else { "le" };
+ return Some(name);
+ }
+ if depth == 24 || depth != 8 * self.components {
+ name += depth.to_string().as_str();
+ }
+ if planar {
+ name.push('p');
+ }
+ if self.get_max_depth() > 8 {
+ name += if self.be { "be" } else { "le" };
+ }
+ Some(name)
+ },
+ ColorModel::YUV(_) => {
+ let max_depth = self.get_max_depth();
+ if self.get_total_depth() != max_depth * self.components {
+ return None;
+ }
+ if self.components < 3 {
+ if self.components == 1 && max_depth == 8 {
+ return Some("y8".to_string());
+ }
+ if self.components == 2 && self.alpha && max_depth == 8 {
+ return Some("y8a".to_string());
+ }
+ return None;
+ }
+ let cu = self.comp_info[1].unwrap();
+ let cv = self.comp_info[2].unwrap();
+ if cu.h_ss != cv.h_ss || cu.v_ss != cv.v_ss || cu.h_ss > 2 || cu.v_ss > 2 {
+ return None;
+ }
+ let mut name = "yuv".to_string();
+ if self.alpha {
+ name.push('a');
+ }
+ name.push('4');
+ let sch = b"421"[cu.h_ss as usize];
+ let tch = if cu.v_ss > 1 { b'0' } else { sch };
+ name.push(sch as char);
+ name.push(tch as char);
+ if self.is_unpacked() {
+ name.push('p');
+ }
+ if max_depth != 8 {
+ name += max_depth.to_string().as_str();
+ }
+ Some(name)
+ },
+ _ => None,
+ }
+ }
}
impl fmt::Display for NAPixelFormaton {
let end = if self.be { "BE" } else { "LE" };
let palstr = if self.palette { "palette " } else { "" };
let astr = if self.alpha { "alpha " } else { "" };
- let mut str = format!("Formaton for {} ({}{}elem {} size {}): ", self.model, palstr, astr,end, self.elem_size);
+ let mut string = format!("Formaton for {} ({}{}elem {} size {}): ", self.model, palstr, astr,end, self.elem_size);
for i in 0..self.comp_info.len() {
if let Some(chr) = self.comp_info[i] {
- str = format!("{} {}", str, chr);
+ string = format!("{} {}", string, chr);
}
}
- write!(f, "[{}]", str)
+ write!(f, "[{}]", string)
+ }
+}
+
+fn parse_rgb_format(s: &str) -> Result<NAPixelFormaton, FormatParseError> {
+ let mut order = [0; 4];
+ let mut is_be = s.ends_with("be");
+ let mut has_alpha = false;
+ let mut pstate = 0;
+ let mut bits = 0;
+ let mut bits_start = 0;
+ for (i, ch) in s.chars().enumerate() {
+ match pstate {
+ 0 => {
+ if i > 4 { return Err(FormatParseError {}); }
+ match ch {
+ 'R' | 'r' => { order[0] = i; },
+ 'G' | 'g' => { order[1] = i; },
+ 'B' | 'b' => { order[2] = i; },
+ 'A' | 'a' => { order[3] = i; has_alpha = true; },
+ '0'..='9' => {
+ pstate = 1; bits_start = i;
+ bits = u32::from((ch as u8) - b'0');
+ },
+ _ => return Err(FormatParseError {}),
+ };
+ },
+ 1 => {
+ if i > 4 + bits_start { return Err(FormatParseError {}); }
+ match ch {
+ '0'..='9' => {
+ bits = (bits * 10) + u32::from((ch as u8) - b'0');
+ },
+ 'B' | 'b' => { pstate = 2; }
+ 'L' | 'l' => { pstate = 2; is_be = false; }
+ _ => return Err(FormatParseError {}),
+ }
+ },
+ 2 => {
+ if ch != 'e' && ch != 'E' { return Err(FormatParseError {}); }
+ pstate = 3;
+ },
+ _ => return Err(FormatParseError {}),
+ };
+ }
+ let components: u8 = if has_alpha { 4 } else { 3 };
+ for el in order.iter() {
+ if *el >= (components as usize) {
+ return Err(FormatParseError {});
+ }
+ }
+ if order[0] == order[1] || order[0] == order[2] || order[1] == order[2] {
+ return Err(FormatParseError {});
+ }
+ if has_alpha && order[0..3].contains(&order[3]) {
+ return Err(FormatParseError {});
+ }
+ let mut chromatons = [None; 5];
+ let elem_size = match bits {
+ 0 | 24 => {
+ for (chro, ord) in chromatons.iter_mut().take(components as usize).zip(order.iter()) {
+ *chro = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: *ord as u8, next_elem: components });
+ }
+ components
+ },
+ 555 => {
+ let rshift = (order[0] * 5) as u8;
+ let gshift = (order[1] * 5) as u8;
+ let bshift = (order[2] * 5) as u8;
+ chromatons[0] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 5, shift: rshift, comp_offs: 0, next_elem: 2 });
+ chromatons[1] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 5, shift: gshift, comp_offs: 0, next_elem: 2 });
+ chromatons[2] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 5, shift: bshift, comp_offs: 0, next_elem: 2 });
+ if has_alpha { return Err(FormatParseError {}); }
+ 2
+ },
+ 565 => {
+ let mut offs = [0; 3];
+ for (ord, off) in order.iter().zip(offs.iter_mut()) {
+ *off = (*ord * 5) as u8;
+ }
+ match order[1] {
+ 0 => { offs[0] += 1; offs[2] += 1; },
+ 1 => { for el in offs.iter_mut() { if *el == 10 { *el += 1; break; } } },
+ _ => {},
+ };
+ chromatons[0] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 5, shift: offs[0], comp_offs: 0, next_elem: 2 });
+ chromatons[1] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 6, shift: offs[1], comp_offs: 0, next_elem: 2 });
+ chromatons[2] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 5, shift: offs[2], comp_offs: 0, next_elem: 2 });
+ if has_alpha { return Err(FormatParseError {}); }
+ 2
+ },
+ 5551 => {
+ let mut offs = [0; 4];
+ let depth = [ 5, 5, 5, 1 ];
+ let mut cur_off = 0;
+ for comp in 0..4 {
+ for (off, ord) in offs.iter_mut().zip(order.iter()) {
+ if *ord == comp {
+ *off = cur_off;
+ cur_off += depth[comp];
+ break;
+ }
+ }
+ }
+ chromatons[0] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 5, shift: offs[0], comp_offs: 0, next_elem: 2 });
+ chromatons[1] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 5, shift: offs[1], comp_offs: 0, next_elem: 2 });
+ chromatons[2] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 5, shift: offs[2], comp_offs: 0, next_elem: 2 });
+ chromatons[3] = Some(NAPixelChromaton { h_ss: 0, v_ss: 0, packed: true, depth: 1, shift: offs[3], comp_offs: 0, next_elem: 2 });
+ if !has_alpha { return Err(FormatParseError {}); }
+ 2
+ },
+ _ => return Err(FormatParseError {}),
+ };
+ Ok(NAPixelFormaton { model: ColorModel::RGB(RGBSubmodel::RGB),
+ components,
+ comp_info: chromatons,
+ elem_size,
+ be: is_be, alpha: has_alpha, palette: false })
+}
+
+fn parse_yuv_format(s: &str) -> Result<NAPixelFormaton, FormatParseError> {
+ match s {
+ "y8" | "y400" | "gray" => {
+ return Ok(NAPixelFormaton {
+ model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 1,
+ comp_info: [
+ Some(NAPixelChromaton{ h_ss: 0, v_ss: 0, packed: false, depth: 8, shift: 0, comp_offs: 0, next_elem: 1 }),
+ None, None, None, None],
+ elem_size: 1, be: true, alpha: false, palette: false });
+ },
+ "y8a" | "y400a" | "graya" => {
+ return Ok(NAPixelFormaton {
+ model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 2,
+ comp_info: [
+ Some(NAPixelChromaton{ h_ss: 0, v_ss: 0, packed: false, depth: 8, shift: 0, comp_offs: 0, next_elem: 2 }),
+ Some(NAPixelChromaton{ h_ss: 0, v_ss: 0, packed: false, depth: 8, shift: 0, comp_offs: 1, next_elem: 2 }),
+ None, None, None],
+ elem_size: 1, be: true, alpha: true, palette: false });
+ },
+ "uyvy" | "y422" => {
+ return Ok(NAPixelFormaton {
+ model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 3,
+ comp_info: [
+ Some(NAPixelChromaton{ h_ss: 0, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 1, next_elem: 2 }),
+ Some(NAPixelChromaton{ h_ss: 1, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 0, next_elem: 4 }),
+ Some(NAPixelChromaton{ h_ss: 1, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 2, next_elem: 4 }),
+ None, None],
+ elem_size: 4, be: false, alpha: false, palette: false });
+ },
+ "yuy2" | "yuyv" | "v422" => {
+ return Ok(NAPixelFormaton {
+ model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 3,
+ comp_info: [
+ Some(NAPixelChromaton{ h_ss: 0, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 0, next_elem: 2 }),
+ Some(NAPixelChromaton{ h_ss: 1, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 1, next_elem: 4 }),
+ Some(NAPixelChromaton{ h_ss: 1, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 3, next_elem: 4 }),
+ None, None],
+ elem_size: 4, be: false, alpha: false, palette: false });
+ },
+ "yvyu" => {
+ return Ok(NAPixelFormaton {
+ model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 3,
+ comp_info: [
+ Some(NAPixelChromaton{ h_ss: 0, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 0, next_elem: 2 }),
+ Some(NAPixelChromaton{ h_ss: 1, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 3, next_elem: 4 }),
+ Some(NAPixelChromaton{ h_ss: 1, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 1, next_elem: 4 }),
+ None, None],
+ elem_size: 4, be: false, alpha: false, palette: false });
+ },
+ "vyuy" => {
+ return Ok(NAPixelFormaton {
+ model: ColorModel::YUV(YUVSubmodel::YUVJ), components: 3,
+ comp_info: [
+ Some(NAPixelChromaton{ h_ss: 0, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 1, next_elem: 2 }),
+ Some(NAPixelChromaton{ h_ss: 1, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 2, next_elem: 4 }),
+ Some(NAPixelChromaton{ h_ss: 1, v_ss: 0, packed: true, depth: 8, shift: 0, comp_offs: 0, next_elem: 4 }),
+ None, None],
+ elem_size: 4, be: false, alpha: false, palette: false });
+ },
+ _ => {},
+ };
+ if !s.starts_with("yuv") {
+ return Err(FormatParseError {});
+ }
+ let has_alpha = s.starts_with("yuva");
+ let components: u8 = if has_alpha { 4 } else { 3 };
+ let mut is_planar = false;
+ let mut format = 0;
+ let mut parse_end = components as usize;
+ for ch in s.chars().skip(components as usize) {
+ parse_end += 1;
+ if ('0'..='9').contains(&ch) {
+ format = format * 10 + u32::from((ch as u8) - b'0');
+ if format > 444 { return Err(FormatParseError {}); }
+ } else {
+ is_planar = ch == 'p';
+ break;
+ }
+ }
+ if format == 0 { return Err(FormatParseError {}); }
+ let depth = if s.len() == parse_end { 8 } else {
+ let mut val = 0;
+ for ch in s.chars().skip(parse_end) {
+ if ('0'..='9').contains(&ch) {
+ val = val * 10 + ((ch as u8) - b'0');
+ if val > 16 { return Err(FormatParseError {}); }
+ } else {
+ break;
+ }
+ }
+ val
+ };
+ if depth == 0 { return Err(FormatParseError {}); }
+ let is_be = s.ends_with("be");
+
+ let mut chromatons = [None; 5];
+ let next_elem = if is_planar { (depth + 7) >> 3 } else {
+ components * ((depth + 7) >> 3) };
+ let subsamp: [[u8; 2]; 4] = match format {
+ 410 => [[0, 0], [2, 2], [2, 2], [0, 0]],
+ 411 => [[0, 0], [2, 0], [2, 0], [0, 0]],
+ 420 => [[0, 0], [1, 1], [1, 1], [0, 0]],
+ 422 => [[0, 0], [1, 0], [1, 0], [0, 0]],
+ 440 => [[0, 0], [0, 1], [0, 1], [0, 0]],
+ 444 => [[0, 0], [0, 0], [0, 0], [0, 0]],
+ _ => return Err(FormatParseError {}),
+ };
+ for (i, (chro, ss)) in chromatons.iter_mut().take(components as usize).zip(subsamp.iter()).enumerate() {
+ *chro = Some(NAPixelChromaton{ h_ss: ss[0], v_ss: ss[1], packed: !is_planar, depth, shift: 0, comp_offs: if is_planar { i as u8 } else { next_elem }, next_elem });
+ }
+ Ok(NAPixelFormaton { model: ColorModel::YUV(YUVSubmodel::YUVJ),
+ components,
+ comp_info: chromatons,
+ elem_size: components,
+ be: is_be, alpha: has_alpha, palette: false })
+}
+
+impl FromStr for NAPixelFormaton {
+ type Err = FormatParseError;
+
+ #[allow(clippy::single_match)]
+ fn from_str(s: &str) -> Result<Self, Self::Err> {
+ match s {
+ "pal8" => return Ok(PAL8_FORMAT),
+ _ => {},
+ }
+ let ret = parse_rgb_format(s);
+ if ret.is_ok() {
+ return ret;
+ }
+ parse_yuv_format(s)
}
}
println!("{}", SND_S16_FORMAT);
println!("{}", SND_U8_FORMAT);
println!("{}", SND_F32P_FORMAT);
+ assert_eq!(SND_U8_FORMAT.to_short_string(), "u8");
+ assert_eq!(SND_F32P_FORMAT.to_short_string(), "f32lep");
+ let s16fmt = SND_S16_FORMAT.to_short_string();
+ assert_eq!(NASoniton::from_str(s16fmt.as_str()).unwrap(), SND_S16_FORMAT);
println!("formaton yuv- {}", YUV420_FORMAT);
println!("formaton pal- {}", PAL8_FORMAT);
println!("formaton rgb565- {}", RGB565_FORMAT);
+
+ let pfmt = NAPixelFormaton::from_str("rgb24").unwrap();
+ assert!(pfmt == RGB24_FORMAT);
+ let pfmt = "gbra";
+ assert_eq!(pfmt, NAPixelFormaton::from_str("gbra").unwrap().to_short_string().unwrap());
+ let pfmt = NAPixelFormaton::from_str("yuv420").unwrap();
+ println!("parsed pfmt as {} / {:?}", pfmt, pfmt.to_short_string());
+ let pfmt = NAPixelFormaton::from_str("yuva420p12").unwrap();
+ println!("parsed pfmt as {} / {:?}", pfmt, pfmt.to_short_string());
+
+ assert_eq!(RGB565_FORMAT.to_short_string().unwrap(), "bgr565le");
+ assert_eq!(PAL8_FORMAT.to_short_string().unwrap(), "pal8");
+ assert_eq!(YUV420_FORMAT.to_short_string().unwrap(), "yuv422p");
+ assert_eq!(YUVA410_FORMAT.to_short_string().unwrap(), "yuva410p");
}
}