From a990de90fe41456a23e58bd087d2f107d321f3a1 Mon Sep 17 00:00:00 2001 From: Valentin Popov Date: Fri, 19 Jul 2024 16:37:58 +0400 Subject: Deleted vendor folder --- vendor/exr/src/meta/attribute.rs | 2226 -------------------------------------- 1 file changed, 2226 deletions(-) delete mode 100644 vendor/exr/src/meta/attribute.rs (limited to 'vendor/exr/src/meta/attribute.rs') diff --git a/vendor/exr/src/meta/attribute.rs b/vendor/exr/src/meta/attribute.rs deleted file mode 100644 index 5b71e82..0000000 --- a/vendor/exr/src/meta/attribute.rs +++ /dev/null @@ -1,2226 +0,0 @@ - -//! Contains all meta data attributes. -//! Each layer can have any number of [`Attribute`]s, including custom attributes. - -use smallvec::SmallVec; - - -/// Contains one of all possible attributes. -/// Includes a variant for custom attributes. -#[derive(Debug, Clone, PartialEq)] -pub enum AttributeValue { - - /// Channel meta data. - ChannelList(ChannelList), - - /// Color space definition. - Chromaticities(Chromaticities), - - /// Compression method of this layer. - Compression(Compression), - - /// This image is an environment map. - EnvironmentMap(EnvironmentMap), - - /// Film roll information. - KeyCode(KeyCode), - - /// Order of the bocks in the file. - LineOrder(LineOrder), - - /// A 3x3 matrix of floats. - Matrix3x3(Matrix3x3), - - /// A 4x4 matrix of floats. - Matrix4x4(Matrix4x4), - - /// 8-bit rgba Preview of the image. - Preview(Preview), - - /// An integer dividend and divisor. - Rational(Rational), - - /// Deep or flat and tiled or scan line. - BlockType(BlockType), - - /// List of texts. - TextVector(Vec), - - /// How to tile up the image. - TileDescription(TileDescription), - - /// Timepoint and more. - TimeCode(TimeCode), - - /// A string of byte-chars. - Text(Text), - - /// 64-bit float - F64(f64), - - /// 32-bit float - F32(f32), - - /// 32-bit signed integer - I32(i32), - - /// 2D integer rectangle. - IntegerBounds(IntegerBounds), - - /// 2D float rectangle. - FloatRect(FloatRect), - - /// 2D integer vector. - IntVec2(Vec2), - - /// 2D float vector. - FloatVec2(Vec2), - - /// 3D integer vector. - IntVec3((i32, i32, i32)), - - /// 3D float vector. - FloatVec3((f32, f32, f32)), - - /// A custom attribute. - /// Contains the type name of this value. - Custom { - - /// The name of the type this attribute is an instance of. - kind: Text, - - /// The value, stored in little-endian byte order, of the value. - /// Use the `exr::io::Data` trait to extract binary values from this vector. - bytes: Vec - }, -} - -/// A byte array with each byte being a char. -/// This is not UTF an must be constructed from a standard string. -// TODO is this ascii? use a rust ascii crate? -#[derive(Clone, PartialEq, Ord, PartialOrd, Default)] // hash implemented manually -pub struct Text { - bytes: TextBytes, -} - -/// Contains time information for this frame within a sequence. -/// Also defined methods to compile this information into a -/// `TV60`, `TV50` or `Film24` bit sequence, packed into `u32`. -/// -/// Satisfies the [SMPTE standard 12M-1999](https://en.wikipedia.org/wiki/SMPTE_timecode). -/// For more in-depth information, see [philrees.co.uk/timecode](http://www.philrees.co.uk/articles/timecode.htm). -#[derive(Copy, Debug, Clone, Eq, PartialEq, Hash, Default)] -pub struct TimeCode { - - /// Hours 0 - 23 are valid. - pub hours: u8, - - /// Minutes 0 - 59 are valid. - pub minutes: u8, - - /// Seconds 0 - 59 are valid. - pub seconds: u8, - - /// Frame Indices 0 - 29 are valid. - pub frame: u8, - - /// Whether this is a drop frame. - pub drop_frame: bool, - - /// Whether this is a color frame. - pub color_frame: bool, - - /// Field Phase. - pub field_phase: bool, - - /// Flags for `TimeCode.binary_groups`. - pub binary_group_flags: [bool; 3], - - /// The user-defined control codes. - /// Every entry in this array can use at most 3 bits. - /// This results in a maximum value of 15, including 0, for each `u8`. - pub binary_groups: [u8; 8] -} - -/// layer type, specifies block type and deepness. -#[derive(Debug, Clone, Copy, Eq, PartialEq, Hash)] -pub enum BlockType { - - /// Corresponds to the string value `scanlineimage`. - ScanLine, - - /// Corresponds to the string value `tiledimage`. - Tile, - - /// Corresponds to the string value `deepscanline`. - DeepScanLine, - - /// Corresponds to the string value `deeptile`. - DeepTile, -} - -/// The string literals used to represent a `BlockType` in a file. -pub mod block_type_strings { - - /// Type attribute text value of flat scan lines - pub const SCAN_LINE: &'static [u8] = b"scanlineimage"; - - /// Type attribute text value of flat tiles - pub const TILE: &'static [u8] = b"tiledimage"; - - /// Type attribute text value of deep scan lines - pub const DEEP_SCAN_LINE: &'static [u8] = b"deepscanline"; - - /// Type attribute text value of deep tiles - pub const DEEP_TILE: &'static [u8] = b"deeptile"; -} - - -pub use crate::compression::Compression; - -/// The integer rectangle describing where an layer is placed on the infinite 2D global space. -pub type DataWindow = IntegerBounds; - -/// The integer rectangle limiting which part of the infinite 2D global space should be displayed. -pub type DisplayWindow = IntegerBounds; - -/// An integer dividend and divisor, together forming a ratio. -pub type Rational = (i32, u32); - -/// A float matrix with four rows and four columns. -pub type Matrix4x4 = [f32; 4*4]; - -/// A float matrix with three rows and three columns. -pub type Matrix3x3 = [f32; 3*3]; - -/// A rectangular section anywhere in 2D integer space. -/// Valid from minimum coordinate (including) `-1,073,741,822` -/// to maximum coordinate (including) `1,073,741,822`, the value of (`i32::MAX/2 -1`). -#[derive(Clone, Copy, Debug, Eq, PartialEq, Default, Hash)] -pub struct IntegerBounds { - - /// The top left corner of this rectangle. - /// The `Box2I32` includes this pixel if the size is not zero. - pub position: Vec2, - - /// How many pixels to include in this `Box2I32`. - /// Extends to the right and downwards. - /// Does not include the actual boundary, just like `Vec::len()`. - pub size: Vec2, -} - -/// A rectangular section anywhere in 2D float space. -#[derive(Clone, Copy, Debug, PartialEq)] -pub struct FloatRect { - - /// The top left corner location of the rectangle (inclusive) - pub min: Vec2, - - /// The bottom right corner location of the rectangle (inclusive) - pub max: Vec2 -} - -/// A List of channels. Channels must be sorted alphabetically. -#[derive(Clone, Debug, Eq, PartialEq, Hash)] -pub struct ChannelList { - - /// The channels in this list. - pub list: SmallVec<[ChannelDescription; 5]>, - - /// The number of bytes that one pixel in this image needs. - // FIXME this needs to account for subsampling anywhere? - pub bytes_per_pixel: usize, // FIXME only makes sense for flat images! - - /// The sample type of all channels, if all channels have the same type. - pub uniform_sample_type: Option, -} - -/// A single channel in an layer. -/// Does not contain the actual pixel data, -/// but instead merely describes it. -#[derive(Clone, Debug, Eq, PartialEq, Hash)] -pub struct ChannelDescription { - - /// One of "R", "G", or "B" most of the time. - pub name: Text, - - /// U32, F16 or F32. - pub sample_type: SampleType, - - /// This attribute only tells lossy compression methods - /// whether this value should be quantized exponentially or linearly. - /// - /// Should be `false` for red, green, or blue channels. - /// Should be `true` for hue, chroma, saturation, or alpha channels. - pub quantize_linearly: bool, - - /// How many of the samples are skipped compared to the other channels in this layer. - /// - /// Can be used for chroma subsampling for manual lossy data compression. - /// Values other than 1 are allowed only in flat, scan-line based images. - /// If an image is deep or tiled, x and y sampling rates for all of its channels must be 1. - pub sampling: Vec2, -} - -/// The type of samples in this channel. -#[derive(Clone, Debug, Eq, PartialEq, Copy, Hash)] -pub enum SampleType { - - /// This channel contains 32-bit unsigned int values. - U32, - - /// This channel contains 16-bit float values. - F16, - - /// This channel contains 32-bit float values. - F32, -} - -/// The color space of the pixels. -/// -/// If a file doesn't have a chromaticities attribute, display software -/// should assume that the file's primaries and the white point match `Rec. ITU-R BT.709-3`. -#[derive(Debug, Clone, Copy, PartialEq)] -pub struct Chromaticities { - - /// "Red" location on the CIE XY chromaticity diagram. - pub red: Vec2, - - /// "Green" location on the CIE XY chromaticity diagram. - pub green: Vec2, - - /// "Blue" location on the CIE XY chromaticity diagram. - pub blue: Vec2, - - /// "White" location on the CIE XY chromaticity diagram. - pub white: Vec2 -} - -/// If this attribute is present, it describes -/// how this texture should be projected onto an environment. -#[derive(Debug, Clone, Copy, Eq, PartialEq, Hash)] -pub enum EnvironmentMap { - - /// This image is an environment map projected like a world map. - LatitudeLongitude, - - /// This image contains the six sides of a cube. - Cube, -} - -/// Uniquely identifies a motion picture film frame. -#[derive(Debug, Clone, Copy, Eq, PartialEq, Hash)] -pub struct KeyCode { - - /// Identifies a film manufacturer. - pub film_manufacturer_code: i32, - - /// Identifies a film type. - pub film_type: i32, - - /// Specifies the film roll prefix. - pub film_roll_prefix: i32, - - /// Specifies the film count. - pub count: i32, - - /// Specifies the perforation offset. - pub perforation_offset: i32, - - /// Specifies the perforation count of each single frame. - pub perforations_per_frame: i32, - - /// Specifies the perforation count of each single film. - pub perforations_per_count: i32, -} - -/// In what order the `Block`s of pixel data appear in a file. -#[derive(Debug, Clone, Copy, Eq, PartialEq, Hash)] -pub enum LineOrder { - - /// The blocks in the file are ordered in descending rows from left to right. - /// When compressing in parallel, this option requires potentially large amounts of memory. - /// In that case, use `LineOrder::Unspecified` for best performance. - Increasing, - - /// The blocks in the file are ordered in ascending rows from right to left. - /// When compressing in parallel, this option requires potentially large amounts of memory. - /// In that case, use `LineOrder::Unspecified` for best performance. - Decreasing, - - /// The blocks are not ordered in a specific way inside the file. - /// In multi-core file writing, this option offers the best performance. - Unspecified, -} - -/// A small `rgba` image of `i8` values that approximates the real exr image. -// TODO is this linear? -#[derive(Clone, Eq, PartialEq)] -pub struct Preview { - - /// The dimensions of the preview image. - pub size: Vec2, - - /// An array with a length of 4 × width × height. - /// The pixels are stored in `LineOrder::Increasing`. - /// Each pixel consists of the four `u8` values red, green, blue, alpha. - pub pixel_data: Vec, -} - -/// Describes how the layer is divided into tiles. -/// Specifies the size of each tile in the image -/// and whether this image contains multiple resolution levels. -#[derive(Debug, Clone, Copy, Eq, PartialEq, Hash)] -pub struct TileDescription { - - /// The size of each tile. - /// Stays the same number of pixels across all levels. - pub tile_size: Vec2, - - /// Whether to also store smaller versions of the image. - pub level_mode: LevelMode, - - /// Whether to round up or down when calculating Mip/Rip levels. - pub rounding_mode: RoundingMode, -} - -/// Whether to also store increasingly smaller versions of the original image. -#[derive(Debug, Clone, Copy, Eq, PartialEq, Hash)] -pub enum LevelMode { - - /// Only a single level. - Singular, - - /// Levels with a similar aspect ratio. - MipMap, - - /// Levels with all possible aspect ratios. - RipMap, -} - - -/// The raw bytes that make up a string in an exr file. -/// Each `u8` is a single char. -// will mostly be "R", "G", "B" or "deepscanlineimage" -pub type TextBytes = SmallVec<[u8; 24]>; - -/// A byte slice, interpreted as text -pub type TextSlice = [u8]; - - -use crate::io::*; -use crate::meta::{sequence_end}; -use crate::error::*; -use crate::math::{RoundingMode, Vec2}; -use half::f16; -use std::convert::{TryFrom}; -use std::borrow::Borrow; -use std::hash::{Hash, Hasher}; -use bit_field::BitField; - - -fn invalid_type() -> Error { - Error::invalid("attribute type mismatch") -} - - -impl Text { - - /// Create a `Text` from an `str` reference. - /// Returns `None` if this string contains unsupported chars. - pub fn new_or_none(string: impl AsRef) -> Option { - let vec : Option = string.as_ref().chars() - .map(|character| u8::try_from(character as u64).ok()) - .collect(); - - vec.map(Self::from_bytes_unchecked) - } - - /// Create a `Text` from an `str` reference. - /// Panics if this string contains unsupported chars. - pub fn new_or_panic(string: impl AsRef) -> Self { - Self::new_or_none(string).expect("exr::Text contains unsupported characters") - } - - /// Create a `Text` from a slice of bytes, - /// without checking any of the bytes. - pub fn from_slice_unchecked(text: &TextSlice) -> Self { - Self::from_bytes_unchecked(SmallVec::from_slice(text)) - } - - /// Create a `Text` from the specified bytes object, - /// without checking any of the bytes. - pub fn from_bytes_unchecked(bytes: TextBytes) -> Self { - Text { bytes } - } - - /// The internal ASCII bytes this text is made of. - pub fn as_slice(&self) -> &TextSlice { - self.bytes.as_slice() - } - - /// Check whether this string is valid, adjusting `long_names` if required. - /// If `long_names` is not provided, text length will be entirely unchecked. - pub fn validate(&self, null_terminated: bool, long_names: Option<&mut bool>) -> UnitResult { - Self::validate_bytes(self.as_slice(), null_terminated, long_names) - } - - /// Check whether some bytes are valid, adjusting `long_names` if required. - /// If `long_names` is not provided, text length will be entirely unchecked. - pub fn validate_bytes(text: &TextSlice, null_terminated: bool, long_names: Option<&mut bool>) -> UnitResult { - if null_terminated && text.is_empty() { - return Err(Error::invalid("text must not be empty")); - } - - if let Some(long) = long_names { - if text.len() >= 256 { return Err(Error::invalid("text must not be longer than 255")); } - if text.len() >= 32 { *long = true; } - } - - Ok(()) - } - - /// The byte count this string would occupy if it were encoded as a null-terminated string. - pub fn null_terminated_byte_size(&self) -> usize { - self.bytes.len() + sequence_end::byte_size() - } - - /// The byte count this string would occupy if it were encoded as a size-prefixed string. - pub fn i32_sized_byte_size(&self) -> usize { - self.bytes.len() + i32::BYTE_SIZE - } - - /// Write the length of a string and then the contents with that length. - pub fn write_i32_sized(&self, write: &mut W) -> UnitResult { - debug_assert!(self.validate( false, None).is_ok(), "text size bug"); - i32::write(usize_to_i32(self.bytes.len()), write)?; - Self::write_unsized_bytes(self.bytes.as_slice(), write) - } - - /// Without validation, write this instance to the byte stream. - fn write_unsized_bytes(bytes: &[u8], write: &mut W) -> UnitResult { - u8::write_slice(write, bytes)?; - Ok(()) - } - - /// Read the length of a string and then the contents with that length. - pub fn read_i32_sized(read: &mut R, max_size: usize) -> Result { - let size = i32_to_usize(i32::read(read)?, "vector size")?; - Ok(Text::from_bytes_unchecked(SmallVec::from_vec(u8::read_vec(read, size, 1024, Some(max_size), "text attribute length")?))) - } - - /// Read the contents with that length. - pub fn read_sized(read: &mut R, size: usize) -> Result { - const SMALL_SIZE: usize = 24; - - // for small strings, read into small vec without heap allocation - if size <= SMALL_SIZE { - let mut buffer = [0_u8; SMALL_SIZE]; - let data = &mut buffer[..size]; - - read.read_exact(data)?; - Ok(Text::from_bytes_unchecked(SmallVec::from_slice(data))) - } - - // for large strings, read a dynamic vec of arbitrary size - else { - Ok(Text::from_bytes_unchecked(SmallVec::from_vec(u8::read_vec(read, size, 1024, None, "text attribute length")?))) - } - } - - /// Write the string contents and a null-terminator. - pub fn write_null_terminated(&self, write: &mut W) -> UnitResult { - Self::write_null_terminated_bytes(self.as_slice(), write) - } - - /// Write the string contents and a null-terminator. - fn write_null_terminated_bytes(bytes: &[u8], write: &mut W) -> UnitResult { - debug_assert!(!bytes.is_empty(), "text is empty bug"); // required to avoid mixup with "sequece_end" - - Text::write_unsized_bytes(bytes, write)?; - sequence_end::write(write)?; - Ok(()) - } - - /// Read a string until the null-terminator is found. Then skips the null-terminator. - pub fn read_null_terminated(read: &mut R, max_len: usize) -> Result { - let mut bytes = smallvec![ u8::read(read)? ]; // null-terminated strings are always at least 1 byte - - loop { - match u8::read(read)? { - 0 => break, - non_terminator => bytes.push(non_terminator), - } - - if bytes.len() > max_len { - return Err(Error::invalid("text too long")) - } - } - - Ok(Text { bytes }) - } - - /// Allows any text length since it is only used for attribute values, - /// but not attribute names, attribute type names, or channel names. - fn read_vec_of_i32_sized( - read: &mut PeekRead, - total_byte_size: usize - ) -> Result> - { - let mut result = Vec::with_capacity(2); - - // length of the text-vector can be inferred from attribute size - let mut processed_bytes = 0; - - while processed_bytes < total_byte_size { - let text = Text::read_i32_sized(read, total_byte_size)?; - processed_bytes += ::std::mem::size_of::(); // size i32 of the text - processed_bytes += text.bytes.len(); - result.push(text); - } - - // the expected byte size did not match the actual text byte size - if processed_bytes != total_byte_size { - return Err(Error::invalid("text array byte size")) - } - - Ok(result) - } - - /// Allows any text length since it is only used for attribute values, - /// but not attribute names, attribute type names, or channel names. - fn write_vec_of_i32_sized_texts(write: &mut W, texts: &[Text]) -> UnitResult { - // length of the text-vector can be inferred from attribute size - for text in texts { - text.write_i32_sized(write)?; - } - - Ok(()) - } - - /// The underlying bytes that represent this text. - pub fn bytes(&self) -> &[u8] { - self.bytes.as_slice() - } - - /// Iterate over the individual chars in this text, similar to `String::chars()`. - /// Does not do any heap-allocation but borrows from this instance instead. - pub fn chars(&self) -> impl '_ + Iterator { - self.bytes.iter().map(|&byte| byte as char) - } - - /// Compare this `exr::Text` with a plain `&str`. - pub fn eq(&self, string: &str) -> bool { - string.chars().eq(self.chars()) - } - - /// Compare this `exr::Text` with a plain `&str` ignoring capitalization. - pub fn eq_case_insensitive(&self, string: &str) -> bool { - // this is technically not working for a "turkish i", but those cannot be encoded in exr files anyways - let self_chars = self.chars().map(|char| char.to_ascii_lowercase()); - let string_chars = string.chars().flat_map(|ch| ch.to_lowercase()); - - string_chars.eq(self_chars) - } -} - -impl PartialEq for Text { - fn eq(&self, other: &str) -> bool { - self.eq(other) - } -} - -impl PartialEq for str { - fn eq(&self, other: &Text) -> bool { - other.eq(self) - } -} - -impl Eq for Text {} - -impl Borrow for Text { - fn borrow(&self) -> &TextSlice { - self.as_slice() - } -} - -// forwarding implementation. guarantees `text.borrow().hash() == text.hash()` (required for Borrow) -impl Hash for Text { - fn hash(&self, state: &mut H) { - self.bytes.hash(state) - } -} - -impl Into for Text { - fn into(self) -> String { - self.to_string() - } -} - -impl<'s> From<&'s str> for Text { - - /// Panics if the string contains an unsupported character - fn from(str: &'s str) -> Self { - Self::new_or_panic(str) - } -} - - -/* TODO (currently conflicts with From<&str>) -impl<'s> TryFrom<&'s str> for Text { - type Error = String; - - fn try_from(value: &'s str) -> std::result::Result { - Text::new_or_none(value) - .ok_or_else(|| format!( - "exr::Text does not support all characters in the string `{}`", - value - )) - } -}*/ - - -impl ::std::fmt::Debug for Text { - fn fmt(&self, f: &mut ::std::fmt::Formatter<'_>) -> ::std::fmt::Result { - write!(f, "exr::Text(\"{}\")", self) - } -} - -// automatically implements to_string for us -impl ::std::fmt::Display for Text { - fn fmt(&self, f: &mut ::std::fmt::Formatter<'_>) -> ::std::fmt::Result { - use std::fmt::Write; - - for &byte in self.bytes.iter() { - f.write_char(byte as char)?; - } - - Ok(()) - } -} - - -impl ChannelList { - - /// Does not validate channel order. - pub fn new(channels: SmallVec<[ChannelDescription; 5]>) -> Self { - let uniform_sample_type = { - if let Some(first) = channels.first() { - let has_uniform_types = channels.iter().skip(1) - .all(|chan| chan.sample_type == first.sample_type); - - if has_uniform_types { Some(first.sample_type) } else { None } - } - else { None } - }; - - ChannelList { - bytes_per_pixel: channels.iter().map(|channel| channel.sample_type.bytes_per_sample()).sum(), - list: channels, uniform_sample_type, - } - } - - /// Iterate over the channels, and adds to each channel the byte offset of the channels sample type. - /// Assumes the internal channel list is properly sorted. - pub fn channels_with_byte_offset(&self) -> impl Iterator { - self.list.iter().scan(0, |byte_position, channel|{ - let previous_position = *byte_position; - *byte_position += channel.sample_type.bytes_per_sample(); - Some((previous_position, channel)) - }) - } - - /// Return the index of the channel with the exact name, case sensitive, or none. - /// Potentially uses less than linear time. - pub fn find_index_of_channel(&self, exact_name: &Text) -> Option { - self.list.binary_search_by_key(&exact_name.bytes(), |chan| chan.name.bytes()).ok() - } - - // TODO use this in compression methods - /*pub fn pixel_section_indices(&self, bounds: IntegerBounds) -> impl '_ + Iterator { - (bounds.position.y() .. bounds.end().y()).flat_map(|y| { - self.list - .filter(|channel| mod_p(y, usize_to_i32(channel.sampling.1)) == 0) - .flat_map(|channel|{ - (bounds.position.x() .. bounds.end().x()) - .filter(|x| mod_p(*x, usize_to_i32(channel.sampling.0)) == 0) - .map(|x| (channel, x, y)) - }) - }) - }*/ -} - -impl BlockType { - - /// The corresponding attribute type name literal - const TYPE_NAME: &'static [u8] = type_names::TEXT; - - /// Return a `BlockType` object from the specified attribute text value. - pub fn parse(text: Text) -> Result { - match text.as_slice() { - block_type_strings::SCAN_LINE => Ok(BlockType::ScanLine), - block_type_strings::TILE => Ok(BlockType::Tile), - - block_type_strings::DEEP_SCAN_LINE => Ok(BlockType::DeepScanLine), - block_type_strings::DEEP_TILE => Ok(BlockType::DeepTile), - - _ => Err(Error::invalid("block type attribute value")), - } - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut impl Write) -> UnitResult { - u8::write_slice(write, self.to_text_bytes())?; - Ok(()) - } - - /// Returns the raw attribute text value this type is represented by in a file. - pub fn to_text_bytes(&self) -> &[u8] { - match self { - BlockType::ScanLine => block_type_strings::SCAN_LINE, - BlockType::Tile => block_type_strings::TILE, - BlockType::DeepScanLine => block_type_strings::DEEP_SCAN_LINE, - BlockType::DeepTile => block_type_strings::DEEP_TILE, - } - } - - /// Number of bytes this would consume in an exr file. - pub fn byte_size(&self) -> usize { - self.to_text_bytes().len() - } -} - - -impl IntegerBounds { - - /// Create a box with no size located at (0,0). - pub fn zero() -> Self { - Self::from_dimensions(Vec2(0, 0)) - } - - /// Create a box with a size starting at zero. - pub fn from_dimensions(size: impl Into>) -> Self { - Self::new(Vec2(0,0), size) - } - - /// Create a box with a size and an origin point. - pub fn new(start: impl Into>, size: impl Into>) -> Self { - Self { position: start.into(), size: size.into() } - } - - /// Returns the top-right coordinate of the rectangle. - /// The row and column described by this vector are not included in the rectangle, - /// just like `Vec::len()`. - pub fn end(self) -> Vec2 { - self.position + self.size.to_i32() // larger than max int32 is panic - } - - /// Returns the maximum coordinate that a value in this rectangle may have. - pub fn max(self) -> Vec2 { - self.end() - Vec2(1,1) - } - - /// Validate this instance. - pub fn validate(&self, max_size: Option>) -> UnitResult { - if let Some(max_size) = max_size { - if self.size.width() > max_size.width() || self.size.height() > max_size.height() { - return Err(Error::invalid("window attribute dimension value")); - } - } - - let min_i64 = Vec2(self.position.x() as i64, self.position.y() as i64); - - let max_i64 = Vec2( - self.position.x() as i64 + self.size.width() as i64, - self.position.y() as i64 + self.size.height() as i64, - ); - - Self::validate_min_max_u64(min_i64, max_i64) - } - - fn validate_min_max_u64(min: Vec2, max: Vec2) -> UnitResult { - let max_box_size_as_i64 = (i32::MAX / 2) as i64; // as defined in the original c++ library - - if max.x() >= max_box_size_as_i64 - || max.y() >= max_box_size_as_i64 - || min.x() <= -max_box_size_as_i64 - || min.y() <= -max_box_size_as_i64 - { - return Err(Error::invalid("window size exceeding integer maximum")); - } - - Ok(()) - } - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { - 4 * i32::BYTE_SIZE - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - let Vec2(x_min, y_min) = self.position; - let Vec2(x_max, y_max) = self.max(); - - x_min.write(write)?; - y_min.write(write)?; - x_max.write(write)?; - y_max.write(write)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - let x_min = i32::read(read)?; - let y_min = i32::read(read)?; - let x_max = i32::read(read)?; - let y_max = i32::read(read)?; - - let min = Vec2(x_min.min(x_max), y_min.min(y_max)); - let max = Vec2(x_min.max(x_max), y_min.max(y_max)); - - // prevent addition overflow - Self::validate_min_max_u64( - Vec2(min.x() as i64, min.y() as i64), - Vec2(max.x() as i64, max.y() as i64), - )?; - - // add one to max because the max inclusive, but the size is not - let size = Vec2(max.x() + 1 - min.x(), max.y() + 1 - min.y()); - let size = size.to_usize("box coordinates")?; - - Ok(IntegerBounds { position: min, size }) - } - - /// Create a new rectangle which is offset by the specified origin. - pub fn with_origin(self, origin: Vec2) -> Self { // TODO rename to "move" or "translate"? - IntegerBounds { position: self.position + origin, .. self } - } - - /// Returns whether the specified rectangle is equal to or inside this rectangle. - pub fn contains(self, subset: Self) -> bool { - subset.position.x() >= self.position.x() - && subset.position.y() >= self.position.y() - && subset.end().x() <= self.end().x() - && subset.end().y() <= self.end().y() - } -} - - -impl FloatRect { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { - 4 * f32::BYTE_SIZE - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - self.min.x().write(write)?; - self.min.y().write(write)?; - self.max.x().write(write)?; - self.max.y().write(write)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - let x_min = f32::read(read)?; - let y_min = f32::read(read)?; - let x_max = f32::read(read)?; - let y_max = f32::read(read)?; - - Ok(FloatRect { - min: Vec2(x_min, y_min), - max: Vec2(x_max, y_max) - }) - } -} - -impl SampleType { - - /// How many bytes a single sample takes up. - pub fn bytes_per_sample(&self) -> usize { - match self { - SampleType::F16 => f16::BYTE_SIZE, - SampleType::F32 => f32::BYTE_SIZE, - SampleType::U32 => u32::BYTE_SIZE, - } - } - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { - i32::BYTE_SIZE - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - match *self { - SampleType::U32 => 0_i32, - SampleType::F16 => 1_i32, - SampleType::F32 => 2_i32, - }.write(write)?; - - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - // there's definitely going to be more than 255 different pixel types in the future - Ok(match i32::read(read)? { - 0 => SampleType::U32, - 1 => SampleType::F16, - 2 => SampleType::F32, - _ => return Err(Error::invalid("pixel type attribute value")), - }) - } -} - -impl ChannelDescription { - /// Choose whether to compress samples linearly or not, based on the channel name. - /// Luminance-based channels will be compressed differently than linear data such as alpha. - pub fn guess_quantization_linearity(name: &Text) -> bool { - !( - name.eq_case_insensitive("R") || name.eq_case_insensitive("G") || - name.eq_case_insensitive("B") || name.eq_case_insensitive("L") || - name.eq_case_insensitive("Y") || name.eq_case_insensitive("X") || - name.eq_case_insensitive("Z") - ) - } - - /// Create a new channel with the specified properties and a sampling rate of (1,1). - /// Automatically chooses the linearity for compression based on the channel name. - pub fn named(name: impl Into, sample_type: SampleType) -> Self { - let name = name.into(); - let linearity = Self::guess_quantization_linearity(&name); - Self::new(name, sample_type, linearity) - } - - /*pub fn from_name + Default>(name: impl Into) -> Self { - Self::named(name, T::default().into().sample_type()) - }*/ - - /// Create a new channel with the specified properties and a sampling rate of (1,1). - pub fn new(name: impl Into, sample_type: SampleType, quantize_linearly: bool) -> Self { - Self { name: name.into(), sample_type, quantize_linearly, sampling: Vec2(1, 1) } - } - - /// The count of pixels this channel contains, respecting subsampling. - // FIXME this must be used everywhere - pub fn subsampled_pixels(&self, dimensions: Vec2) -> usize { - self.subsampled_resolution(dimensions).area() - } - - /// The resolution pf this channel, respecting subsampling. - pub fn subsampled_resolution(&self, dimensions: Vec2) -> Vec2 { - dimensions / self.sampling - } - - /// Number of bytes this would consume in an exr file. - pub fn byte_size(&self) -> usize { - self.name.null_terminated_byte_size() - + SampleType::byte_size() - + 1 // is_linear - + 3 // reserved bytes - + 2 * u32::BYTE_SIZE // sampling x, y - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - Text::write_null_terminated(&self.name, write)?; - self.sample_type.write(write)?; - - match self.quantize_linearly { - false => 0_u8, - true => 1_u8, - }.write(write)?; - - i8::write_slice(write, &[0_i8, 0_i8, 0_i8])?; - i32::write(usize_to_i32(self.sampling.x()), write)?; - i32::write(usize_to_i32(self.sampling.y()), write)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - let name = Text::read_null_terminated(read, 256)?; - let sample_type = SampleType::read(read)?; - - let is_linear = match u8::read(read)? { - 1 => true, - 0 => false, - _ => return Err(Error::invalid("channel linearity attribute value")), - }; - - let mut reserved = [0_i8; 3]; - i8::read_slice(read, &mut reserved)?; - - let x_sampling = i32_to_usize(i32::read(read)?, "x channel sampling")?; - let y_sampling = i32_to_usize(i32::read(read)?, "y channel sampling")?; - - Ok(ChannelDescription { - name, sample_type, - quantize_linearly: is_linear, - sampling: Vec2(x_sampling, y_sampling), - }) - } - - /// Validate this instance. - pub fn validate(&self, allow_sampling: bool, data_window: IntegerBounds, strict: bool) -> UnitResult { - self.name.validate(true, None)?; // TODO spec says this does not affect `requirements.long_names` but is that true? - - if self.sampling.x() == 0 || self.sampling.y() == 0 { - return Err(Error::invalid("zero sampling factor")); - } - - if strict && !allow_sampling && self.sampling != Vec2(1,1) { - return Err(Error::invalid("subsampling is only allowed in flat scan line images")); - } - - if data_window.position.x() % self.sampling.x() as i32 != 0 || data_window.position.y() % self.sampling.y() as i32 != 0 { - return Err(Error::invalid("channel sampling factor not dividing data window position")); - } - - if data_window.size.x() % self.sampling.x() != 0 || data_window.size.y() % self.sampling.y() != 0 { - return Err(Error::invalid("channel sampling factor not dividing data window size")); - } - - if self.sampling != Vec2(1,1) { - // TODO this must only be implemented in the crate::image module and child modules, - // should not be too difficult - - return Err(Error::unsupported("channel subsampling not supported yet")); - } - - Ok(()) - } -} - -impl ChannelList { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size(&self) -> usize { - self.list.iter().map(ChannelDescription::byte_size).sum::() + sequence_end::byte_size() - } - - /// Without validation, write this instance to the byte stream. - /// Assumes channels are sorted alphabetically and all values are validated. - pub fn write(&self, write: &mut impl Write) -> UnitResult { - for channel in &self.list { - channel.write(write)?; - } - - sequence_end::write(write)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut PeekRead) -> Result { - let mut channels = SmallVec::new(); - while !sequence_end::has_come(read)? { - channels.push(ChannelDescription::read(read)?); - } - - Ok(ChannelList::new(channels)) - } - - /// Check if channels are valid and sorted. - pub fn validate(&self, allow_sampling: bool, data_window: IntegerBounds, strict: bool) -> UnitResult { - let mut iter = self.list.iter().map(|chan| chan.validate(allow_sampling, data_window, strict).map(|_| &chan.name)); - let mut previous = iter.next().ok_or(Error::invalid("at least one channel is required"))??; - - for result in iter { - let value = result?; - if strict && previous == value { return Err(Error::invalid("channel names are not unique")); } - else if previous > value { return Err(Error::invalid("channel names are not sorted alphabetically")); } - else { previous = value; } - } - - Ok(()) - } -} - -fn u8_to_decimal32(binary: u8) -> u32 { - let units = binary as u32 % 10; - let tens = (binary as u32 / 10) % 10; - units | (tens << 4) -} - -// assumes value fits into u8 -fn u8_from_decimal32(coded: u32) -> u8 { - ((coded & 0x0f) + 10 * ((coded >> 4) & 0x0f)) as u8 -} - -// https://github.com/AcademySoftwareFoundation/openexr/blob/master/src/lib/OpenEXR/ImfTimeCode.cpp -impl TimeCode { - - /// Number of bytes this would consume in an exr file. - pub const BYTE_SIZE: usize = 2 * u32::BYTE_SIZE; - - /// Returns an error if this time code is considered invalid. - pub fn validate(&self, strict: bool) -> UnitResult { - if strict { - if self.frame > 29 { Err(Error::invalid("time code frame larger than 29")) } - else if self.seconds > 59 { Err(Error::invalid("time code seconds larger than 59")) } - else if self.minutes > 59 { Err(Error::invalid("time code minutes larger than 59")) } - else if self.hours > 23 { Err(Error::invalid("time code hours larger than 23")) } - else if self.binary_groups.iter().any(|&group| group > 15) { - Err(Error::invalid("time code binary group value too large for 3 bits")) - } - else { Ok(()) } - } - else { Ok(()) } - } - - - /// Pack the SMPTE time code into a u32 value, according to TV60 packing. - /// This is the encoding which is used within a binary exr file. - pub fn pack_time_as_tv60_u32(&self) -> Result { - // validate strictly to prevent set_bit panic! below - self.validate(true)?; - - Ok(*0_u32 - .set_bits(0..6, u8_to_decimal32(self.frame)) - .set_bit(6, self.drop_frame) - .set_bit(7, self.color_frame) - .set_bits(8..15, u8_to_decimal32(self.seconds)) - .set_bit(15, self.field_phase) - .set_bits(16..23, u8_to_decimal32(self.minutes)) - .set_bit(23, self.binary_group_flags[0]) - .set_bits(24..30, u8_to_decimal32(self.hours)) - .set_bit(30, self.binary_group_flags[1]) - .set_bit(31, self.binary_group_flags[2]) - ) - } - - /// Unpack a time code from one TV60 encoded u32 value and the encoded user data. - /// This is the encoding which is used within a binary exr file. - pub fn from_tv60_time(tv60_time: u32, user_data: u32) -> Self { - Self { - frame: u8_from_decimal32(tv60_time.get_bits(0..6)), // cast cannot fail, as these are less than 8 bits - drop_frame: tv60_time.get_bit(6), - color_frame: tv60_time.get_bit(7), - seconds: u8_from_decimal32(tv60_time.get_bits(8..15)), // cast cannot fail, as these are less than 8 bits - field_phase: tv60_time.get_bit(15), - minutes: u8_from_decimal32(tv60_time.get_bits(16..23)), // cast cannot fail, as these are less than 8 bits - hours: u8_from_decimal32(tv60_time.get_bits(24..30)), // cast cannot fail, as these are less than 8 bits - binary_group_flags: [ - tv60_time.get_bit(23), - tv60_time.get_bit(30), - tv60_time.get_bit(31), - ], - - binary_groups: Self::unpack_user_data_from_u32(user_data) - } - } - - /// Pack the SMPTE time code into a u32 value, according to TV50 packing. - /// This encoding does not support the `drop_frame` flag, it will be lost. - pub fn pack_time_as_tv50_u32(&self) -> Result { - Ok(*self.pack_time_as_tv60_u32()? - - // swap some fields by replacing some bits in the packed u32 - .set_bit(6, false) - .set_bit(15, self.binary_group_flags[0]) - .set_bit(30, self.binary_group_flags[1]) - .set_bit(23, self.binary_group_flags[2]) - .set_bit(31, self.field_phase) - ) - } - - /// Unpack a time code from one TV50 encoded u32 value and the encoded user data. - /// This encoding does not support the `drop_frame` flag, it will always be false. - pub fn from_tv50_time(tv50_time: u32, user_data: u32) -> Self { - Self { - drop_frame: false, // do not use bit [6] - - // swap some fields: - field_phase: tv50_time.get_bit(31), - binary_group_flags: [ - tv50_time.get_bit(15), - tv50_time.get_bit(30), - tv50_time.get_bit(23), - ], - - .. Self::from_tv60_time(tv50_time, user_data) - } - } - - - /// Pack the SMPTE time code into a u32 value, according to FILM24 packing. - /// This encoding does not support the `drop_frame` and `color_frame` flags, they will be lost. - pub fn pack_time_as_film24_u32(&self) -> Result { - Ok(*self.pack_time_as_tv60_u32()? - .set_bit(6, false) - .set_bit(7, false) - ) - } - - /// Unpack a time code from one TV60 encoded u32 value and the encoded user data. - /// This encoding does not support the `drop_frame` and `color_frame` flags, they will always be `false`. - pub fn from_film24_time(film24_time: u32, user_data: u32) -> Self { - Self { - drop_frame: false, // bit [6] - color_frame: false, // bit [7] - .. Self::from_tv60_time(film24_time, user_data) - } - } - - - // in rust, group index starts at zero, not at one. - fn user_data_bit_indices(group_index: usize) -> std::ops::Range { - let min_bit = 4 * group_index; - min_bit .. min_bit + 4 // +4, not +3, as `Range` is exclusive - } - - /// Pack the user data `u8` array into one u32. - /// User data values are clamped to the valid range (maximum value is 4). - pub fn pack_user_data_as_u32(&self) -> u32 { - let packed = self.binary_groups.iter().enumerate().fold(0_u32, |mut packed, (group_index, group_value)| - *packed.set_bits(Self::user_data_bit_indices(group_index), *group_value.min(&15) as u32) - ); - - debug_assert_eq!(Self::unpack_user_data_from_u32(packed), self.binary_groups, "round trip user data encoding"); - packed - } - - // Unpack the encoded u32 user data to an array of bytes, each byte having a value from 0 to 4. - fn unpack_user_data_from_u32(user_data: u32) -> [u8; 8] { - (0..8).map(|group_index| user_data.get_bits(Self::user_data_bit_indices(group_index)) as u8) - .collect::>().into_inner().expect("array index bug") - } - - - /// Write this time code to the byte stream, encoded as TV60 integers. - /// Returns an `Error::Invalid` if the fields are out of the allowed range. - pub fn write(&self, write: &mut W) -> UnitResult { - self.pack_time_as_tv60_u32()?.write(write)?; // will validate - self.pack_user_data_as_u32().write(write)?; - Ok(()) - } - - /// Read the time code, without validating, extracting from TV60 integers. - pub fn read(read: &mut R) -> Result { - let time_and_flags = u32::read(read)?; - let user_data = u32::read(read)?; - Ok(Self::from_tv60_time(time_and_flags, user_data)) - } -} - -impl Chromaticities { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { - 8 * f32::BYTE_SIZE - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - self.red.x().write(write)?; - self.red.y().write(write)?; - - self.green.x().write(write)?; - self.green.y().write(write)?; - - self.blue.x().write(write)?; - self.blue.y().write(write)?; - - self.white.x().write(write)?; - self.white.y().write(write)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - Ok(Chromaticities { - red: Vec2(f32::read(read)?, f32::read(read)?), - green: Vec2(f32::read(read)?, f32::read(read)?), - blue: Vec2(f32::read(read)?, f32::read(read)?), - white: Vec2(f32::read(read)?, f32::read(read)?), - }) - } -} - -impl Compression { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { u8::BYTE_SIZE } - - /// Without validation, write this instance to the byte stream. - pub fn write(self, write: &mut W) -> UnitResult { - use self::Compression::*; - match self { - Uncompressed => 0_u8, - RLE => 1_u8, - ZIP1 => 2_u8, - ZIP16 => 3_u8, - PIZ => 4_u8, - PXR24 => 5_u8, - B44 => 6_u8, - B44A => 7_u8, - DWAA(_) => 8_u8, - DWAB(_) => 9_u8, - }.write(write)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - use self::Compression::*; - Ok(match u8::read(read)? { - 0 => Uncompressed, - 1 => RLE, - 2 => ZIP1, - 3 => ZIP16, - 4 => PIZ, - 5 => PXR24, - 6 => B44, - 7 => B44A, - 8 => DWAA(None), - 9 => DWAB(None), - _ => return Err(Error::unsupported("unknown compression method")), - }) - } -} - -impl EnvironmentMap { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { - u8::BYTE_SIZE - } - - /// Without validation, write this instance to the byte stream. - pub fn write(self, write: &mut W) -> UnitResult { - use self::EnvironmentMap::*; - match self { - LatitudeLongitude => 0_u8, - Cube => 1_u8 - }.write(write)?; - - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - use self::EnvironmentMap::*; - Ok(match u8::read(read)? { - 0 => LatitudeLongitude, - 1 => Cube, - _ => return Err(Error::invalid("environment map attribute value")), - }) - } -} - -impl KeyCode { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { - 6 * i32::BYTE_SIZE - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - self.film_manufacturer_code.write(write)?; - self.film_type.write(write)?; - self.film_roll_prefix.write(write)?; - self.count.write(write)?; - self.perforation_offset.write(write)?; - self.perforations_per_count.write(write)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - Ok(KeyCode { - film_manufacturer_code: i32::read(read)?, - film_type: i32::read(read)?, - film_roll_prefix: i32::read(read)?, - count: i32::read(read)?, - perforation_offset: i32::read(read)?, - perforations_per_frame: i32::read(read)?, - perforations_per_count: i32::read(read)?, - }) - } -} - -impl LineOrder { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { - u8::BYTE_SIZE - } - - /// Without validation, write this instance to the byte stream. - pub fn write(self, write: &mut W) -> UnitResult { - use self::LineOrder::*; - match self { - Increasing => 0_u8, - Decreasing => 1_u8, - Unspecified => 2_u8, - }.write(write)?; - - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - use self::LineOrder::*; - Ok(match u8::read(read)? { - 0 => Increasing, - 1 => Decreasing, - 2 => Unspecified, - _ => return Err(Error::invalid("line order attribute value")), - }) - } -} - - - - -impl Preview { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size(&self) -> usize { - 2 * u32::BYTE_SIZE + self.pixel_data.len() - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - u32::write(self.size.width() as u32, write)?; - u32::write(self.size.height() as u32, write)?; - - i8::write_slice(write, &self.pixel_data)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - let width = u32::read(read)? as usize; - let height = u32::read(read)? as usize; - - if let Some(pixel_count) = width.checked_mul(height) { - // Multiply by the number of bytes per pixel. - if let Some(byte_count) = pixel_count.checked_mul(4) { - let pixel_data = i8::read_vec( - read, - byte_count, - 1024 * 1024 * 4, - None, - "preview attribute pixel count", - )?; - - let preview = Preview { - size: Vec2(width, height), - pixel_data, - }; - - return Ok(preview); - } - } - - return Err(Error::invalid( - format!("Overflow while calculating preview image Attribute size \ - (width: {}, height: {}).", - width, - height))); - } - - /// Validate this instance. - pub fn validate(&self, strict: bool) -> UnitResult { - if strict && (self.size.area() * 4 != self.pixel_data.len()) { - return Err(Error::invalid("preview dimensions do not match content length")) - } - - Ok(()) - } -} - -impl ::std::fmt::Debug for Preview { - fn fmt(&self, f: &mut ::std::fmt::Formatter<'_>) -> ::std::fmt::Result { - write!(f, "Preview ({}x{} px)", self.size.width(), self.size.height()) - } -} - -impl TileDescription { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size() -> usize { - 2 * u32::BYTE_SIZE + 1 // size x,y + (level mode + rounding mode) - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - u32::write(self.tile_size.width() as u32, write)?; - u32::write(self.tile_size.height() as u32, write)?; - - let level_mode = match self.level_mode { - LevelMode::Singular => 0_u8, - LevelMode::MipMap => 1_u8, - LevelMode::RipMap => 2_u8, - }; - - let rounding_mode = match self.rounding_mode { - RoundingMode::Down => 0_u8, - RoundingMode::Up => 1_u8, - }; - - let mode: u8 = level_mode + (rounding_mode * 16); - mode.write(write)?; - Ok(()) - } - - /// Read the value without validating. - pub fn read(read: &mut R) -> Result { - let x_size = u32::read(read)? as usize; - let y_size = u32::read(read)? as usize; - - let mode = u8::read(read)?; - - // wow you really saved that one byte here - // mode = level_mode + (rounding_mode * 16) - let level_mode = mode & 0b00001111; // wow that works - let rounding_mode = mode >> 4; // wow that works - - let level_mode = match level_mode { - 0 => LevelMode::Singular, - 1 => LevelMode::MipMap, - 2 => LevelMode::RipMap, - _ => return Err(Error::invalid("tile description level mode")), - }; - - let rounding_mode = match rounding_mode { - 0 => RoundingMode::Down, - 1 => RoundingMode::Up, - _ => return Err(Error::invalid("tile description rounding mode")), - }; - - Ok(TileDescription { tile_size: Vec2(x_size, y_size), level_mode, rounding_mode, }) - } - - /// Validate this instance. - pub fn validate(&self) -> UnitResult { - let max = i32::MAX as i64 / 2; - - if self.tile_size.width() == 0 || self.tile_size.height() == 0 - || self.tile_size.width() as i64 >= max || self.tile_size.height() as i64 >= max - { - return Err(Error::invalid("tile size")) - } - - Ok(()) - } -} - - -/// Number of bytes this attribute would consume in an exr file. -// TODO instead of pre calculating byte size, write to a tmp buffer whose length is inspected before actually writing? -pub fn byte_size(name: &Text, value: &AttributeValue) -> usize { - name.null_terminated_byte_size() - + value.kind_name().len() + sequence_end::byte_size() - + i32::BYTE_SIZE // serialized byte size - + value.byte_size() -} - -/// Without validation, write this attribute to the byte stream. -pub fn write(name: &[u8], value: &AttributeValue, write: &mut W) -> UnitResult { - Text::write_null_terminated_bytes(name, write)?; - Text::write_null_terminated_bytes(value.kind_name(), write)?; - i32::write(value.byte_size() as i32, write)?; - value.write(write) -} - -/// Read the attribute without validating. The result may be `Ok` even if this single attribute is invalid. -pub fn read(read: &mut PeekRead, max_size: usize) -> Result<(Text, Result)> { - let name = Text::read_null_terminated(read, max_size)?; - let kind = Text::read_null_terminated(read, max_size)?; - let size = i32_to_usize(i32::read(read)?, "attribute size")?; - let value = AttributeValue::read(read, kind, size)?; - Ok((name, value)) -} - -/// Validate this attribute. -pub fn validate(name: &Text, value: &AttributeValue, long_names: &mut bool, allow_sampling: bool, data_window: IntegerBounds, strict: bool) -> UnitResult { - name.validate(true, Some(long_names))?; // only name text has length restriction - value.validate(allow_sampling, data_window, strict) // attribute value text length is never restricted -} - - -impl AttributeValue { - - /// Number of bytes this would consume in an exr file. - pub fn byte_size(&self) -> usize { - use self::AttributeValue::*; - - match *self { - IntegerBounds(_) => self::IntegerBounds::byte_size(), - FloatRect(_) => self::FloatRect::byte_size(), - - I32(_) => i32::BYTE_SIZE, - F32(_) => f32::BYTE_SIZE, - F64(_) => f64::BYTE_SIZE, - - Rational(_) => { i32::BYTE_SIZE + u32::BYTE_SIZE }, - TimeCode(_) => self::TimeCode::BYTE_SIZE, - - IntVec2(_) => { 2 * i32::BYTE_SIZE }, - FloatVec2(_) => { 2 * f32::BYTE_SIZE }, - IntVec3(_) => { 3 * i32::BYTE_SIZE }, - FloatVec3(_) => { 3 * f32::BYTE_SIZE }, - - ChannelList(ref channels) => channels.byte_size(), - Chromaticities(_) => self::Chromaticities::byte_size(), - Compression(_) => self::Compression::byte_size(), - EnvironmentMap(_) => self::EnvironmentMap::byte_size(), - - KeyCode(_) => self::KeyCode::byte_size(), - LineOrder(_) => self::LineOrder::byte_size(), - - Matrix3x3(ref value) => value.len() * f32::BYTE_SIZE, - Matrix4x4(ref value) => value.len() * f32::BYTE_SIZE, - - Preview(ref value) => value.byte_size(), - - // attribute value texts never have limited size. - // also, don't serialize size, as it can be inferred from attribute size - Text(ref value) => value.bytes.len(), - - TextVector(ref value) => value.iter().map(self::Text::i32_sized_byte_size).sum(), - TileDescription(_) => self::TileDescription::byte_size(), - Custom { ref bytes, .. } => bytes.len(), - BlockType(ref kind) => kind.byte_size() - } - } - - /// The exr name string of the type that an attribute can have. - pub fn kind_name(&self) -> &[u8] { - use self::AttributeValue::*; - use self::type_names as ty; - - match *self { - IntegerBounds(_) => ty::I32BOX2, - FloatRect(_) => ty::F32BOX2, - I32(_) => ty::I32, - F32(_) => ty::F32, - F64(_) => ty::F64, - Rational(_) => ty::RATIONAL, - TimeCode(_) => ty::TIME_CODE, - IntVec2(_) => ty::I32VEC2, - FloatVec2(_) => ty::F32VEC2, - IntVec3(_) => ty::I32VEC3, - FloatVec3(_) => ty::F32VEC3, - ChannelList(_) => ty::CHANNEL_LIST, - Chromaticities(_) => ty::CHROMATICITIES, - Compression(_) => ty::COMPRESSION, - EnvironmentMap(_) => ty::ENVIRONMENT_MAP, - KeyCode(_) => ty::KEY_CODE, - LineOrder(_) => ty::LINE_ORDER, - Matrix3x3(_) => ty::F32MATRIX3X3, - Matrix4x4(_) => ty::F32MATRIX4X4, - Preview(_) => ty::PREVIEW, - Text(_) => ty::TEXT, - TextVector(_) => ty::TEXT_VECTOR, - TileDescription(_) => ty::TILES, - Custom { ref kind, .. } => &kind.bytes, - BlockType(_) => super::BlockType::TYPE_NAME, - } - } - - /// Without validation, write this instance to the byte stream. - pub fn write(&self, write: &mut W) -> UnitResult { - use self::AttributeValue::*; - match *self { - IntegerBounds(value) => value.write(write)?, - FloatRect(value) => value.write(write)?, - - I32(value) => value.write(write)?, - F32(value) => value.write(write)?, - F64(value) => value.write(write)?, - - Rational((a, b)) => { a.write(write)?; b.write(write)?; }, - TimeCode(codes) => { codes.write(write)?; }, - - IntVec2(Vec2(x, y)) => { x.write(write)?; y.write(write)?; }, - FloatVec2(Vec2(x, y)) => { x.write(write)?; y.write(write)?; }, - IntVec3((x, y, z)) => { x.write(write)?; y.write(write)?; z.write(write)?; }, - FloatVec3((x, y, z)) => { x.write(write)?; y.write(write)?; z.write(write)?; }, - - ChannelList(ref channels) => channels.write(write)?, - Chromaticities(ref value) => value.write(write)?, - Compression(value) => value.write(write)?, - EnvironmentMap(value) => value.write(write)?, - - KeyCode(value) => value.write(write)?, - LineOrder(value) => value.write(write)?, - - Matrix3x3(mut value) => f32::write_slice(write, &mut value)?, - Matrix4x4(mut value) => f32::write_slice(write, &mut value)?, - - Preview(ref value) => { value.write(write)?; }, - - // attribute value texts never have limited size. - // also, don't serialize size, as it can be inferred from attribute size - Text(ref value) => u8::write_slice(write, value.bytes.as_slice())?, - - TextVector(ref value) => self::Text::write_vec_of_i32_sized_texts(write, value)?, - TileDescription(ref value) => value.write(write)?, - Custom { ref bytes, .. } => u8::write_slice(write, &bytes)?, // write.write(&bytes).map(|_| ()), - BlockType(kind) => kind.write(write)? - }; - - Ok(()) - } - - /// Read the value without validating. - /// Returns `Ok(Ok(attribute))` for valid attributes. - /// Returns `Ok(Err(Error))` for invalid attributes from a valid byte source. - /// Returns `Err(Error)` for invalid byte sources, for example for invalid files. - pub fn read(read: &mut PeekRead, kind: Text, byte_size: usize) -> Result> { - use self::AttributeValue::*; - use self::type_names as ty; - - // always read bytes - let attribute_bytes = u8::read_vec(read, byte_size, 128, None, "attribute value size")?; - // TODO no allocation for small attributes // : SmallVec<[u8; 64]> = smallvec![0; byte_size]; - - let parse_attribute = move || { - let reader = &mut attribute_bytes.as_slice(); - - Ok(match kind.bytes.as_slice() { - ty::I32BOX2 => IntegerBounds(self::IntegerBounds::read(reader)?), - ty::F32BOX2 => FloatRect(self::FloatRect::read(reader)?), - - ty::I32 => I32(i32::read(reader)?), - ty::F32 => F32(f32::read(reader)?), - ty::F64 => F64(f64::read(reader)?), - - ty::RATIONAL => Rational({ - let a = i32::read(reader)?; - let b = u32::read(reader)?; - (a, b) - }), - - ty::TIME_CODE => TimeCode(self::TimeCode::read(reader)?), - - ty::I32VEC2 => IntVec2({ - let a = i32::read(reader)?; - let b = i32::read(reader)?; - Vec2(a, b) - }), - - ty::F32VEC2 => FloatVec2({ - let a = f32::read(reader)?; - let b = f32::read(reader)?; - Vec2(a, b) - }), - - ty::I32VEC3 => IntVec3({ - let a = i32::read(reader)?; - let b = i32::read(reader)?; - let c = i32::read(reader)?; - (a, b, c) - }), - - ty::F32VEC3 => FloatVec3({ - let a = f32::read(reader)?; - let b = f32::read(reader)?; - let c = f32::read(reader)?; - (a, b, c) - }), - - ty::CHANNEL_LIST => ChannelList(self::ChannelList::read(&mut PeekRead::new(attribute_bytes.as_slice()))?), - ty::CHROMATICITIES => Chromaticities(self::Chromaticities::read(reader)?), - ty::COMPRESSION => Compression(self::Compression::read(reader)?), - ty::ENVIRONMENT_MAP => EnvironmentMap(self::EnvironmentMap::read(reader)?), - - ty::KEY_CODE => KeyCode(self::KeyCode::read(reader)?), - ty::LINE_ORDER => LineOrder(self::LineOrder::read(reader)?), - - ty::F32MATRIX3X3 => Matrix3x3({ - let mut result = [0.0_f32; 9]; - f32::read_slice(reader, &mut result)?; - result - }), - - ty::F32MATRIX4X4 => Matrix4x4({ - let mut result = [0.0_f32; 16]; - f32::read_slice(reader, &mut result)?; - result - }), - - ty::PREVIEW => Preview(self::Preview::read(reader)?), - ty::TEXT => Text(self::Text::read_sized(reader, byte_size)?), - - // the number of strings can be inferred from the total attribute size - ty::TEXT_VECTOR => TextVector(self::Text::read_vec_of_i32_sized( - &mut PeekRead::new(attribute_bytes.as_slice()), - byte_size - )?), - - ty::TILES => TileDescription(self::TileDescription::read(reader)?), - - _ => Custom { kind: kind.clone(), bytes: attribute_bytes.clone() } // TODO no clone - }) - }; - - Ok(parse_attribute()) - } - - /// Validate this instance. - pub fn validate(&self, allow_sampling: bool, data_window: IntegerBounds, strict: bool) -> UnitResult { - use self::AttributeValue::*; - - match *self { - ChannelList(ref channels) => channels.validate(allow_sampling, data_window, strict)?, - TileDescription(ref value) => value.validate()?, - Preview(ref value) => value.validate(strict)?, - TimeCode(ref time_code) => time_code.validate(strict)?, - - TextVector(ref vec) => if strict && vec.is_empty() { - return Err(Error::invalid("text vector may not be empty")) - }, - - _ => {} - }; - - Ok(()) - } - - - /// Return `Ok(i32)` if this attribute is an i32. - pub fn to_i32(&self) -> Result { - match *self { - AttributeValue::I32(value) => Ok(value), - _ => Err(invalid_type()) - } - } - - /// Return `Ok(f32)` if this attribute is an f32. - pub fn to_f32(&self) -> Result { - match *self { - AttributeValue::F32(value) => Ok(value), - _ => Err(invalid_type()) - } - } - - /// Return `Ok(Text)` if this attribute is a text. - pub fn into_text(self) -> Result { - match self { - AttributeValue::Text(value) => Ok(value), - _ => Err(invalid_type()) - } - } - - /// Return `Ok(Text)` if this attribute is a text. - pub fn to_text(&self) -> Result<&Text> { - match self { - AttributeValue::Text(value) => Ok(value), - _ => Err(invalid_type()) - } - } - - /// Return `Ok(Chromaticities)` if this attribute is a chromaticities attribute. - pub fn to_chromaticities(&self) -> Result { - match *self { - AttributeValue::Chromaticities(value) => Ok(value), - _ => Err(invalid_type()) - } - } - - /// Return `Ok(TimeCode)` if this attribute is a time code. - pub fn to_time_code(&self) -> Result { - match *self { - AttributeValue::TimeCode(value) => Ok(value), - _ => Err(invalid_type()) - } - } -} - - - -/// Contains string literals identifying the type of an attribute. -pub mod type_names { - macro_rules! define_attribute_type_names { - ( $($name: ident : $value: expr),* ) => { - $( - /// The byte-string name of this attribute type as it appears in an exr file. - pub const $name: &'static [u8] = $value; - )* - }; - } - - define_attribute_type_names! { - I32BOX2: b"box2i", - F32BOX2: b"box2f", - I32: b"int", - F32: b"float", - F64: b"double", - RATIONAL: b"rational", - TIME_CODE: b"timecode", - I32VEC2: b"v2i", - F32VEC2: b"v2f", - I32VEC3: b"v3i", - F32VEC3: b"v3f", - CHANNEL_LIST: b"chlist", - CHROMATICITIES: b"chromaticities", - COMPRESSION: b"compression", - ENVIRONMENT_MAP:b"envmap", - KEY_CODE: b"keycode", - LINE_ORDER: b"lineOrder", - F32MATRIX3X3: b"m33f", - F32MATRIX4X4: b"m44f", - PREVIEW: b"preview", - TEXT: b"string", - TEXT_VECTOR: b"stringvector", - TILES: b"tiledesc" - } -} - - -#[cfg(test)] -mod test { - use super::*; - use ::std::io::Cursor; - use rand::{random, thread_rng, Rng}; - - #[test] - fn text_ord() { - for _ in 0..1024 { - let text1 = Text::from_bytes_unchecked((0..4).map(|_| rand::random::()).collect()); - let text2 = Text::from_bytes_unchecked((0..4).map(|_| rand::random::()).collect()); - - assert_eq!(text1.to_string().cmp(&text2.to_string()), text1.cmp(&text2), "in text {:?} vs {:?}", text1, text2); - } - } - - #[test] - fn rounding_up(){ - let round_up = RoundingMode::Up; - assert_eq!(round_up.divide(10, 10), 1, "divide equal"); - assert_eq!(round_up.divide(10, 2), 5, "divide even"); - assert_eq!(round_up.divide(10, 5), 2, "divide even"); - - assert_eq!(round_up.divide(8, 5), 2, "round up"); - assert_eq!(round_up.divide(10, 3), 4, "round up"); - assert_eq!(round_up.divide(100, 50), 2, "divide even"); - assert_eq!(round_up.divide(100, 49), 3, "round up"); - } - - #[test] - fn rounding_down(){ - let round_down = RoundingMode::Down; - assert_eq!(round_down.divide(8, 5), 1, "round down"); - assert_eq!(round_down.divide(10, 3), 3, "round down"); - assert_eq!(round_down.divide(100, 50), 2, "divide even"); - assert_eq!(round_down.divide(100, 49), 2, "round down"); - assert_eq!(round_down.divide(100, 51), 1, "round down"); - } - - #[test] - fn tile_description_write_read_roundtrip(){ - let tiles = [ - TileDescription { - tile_size: Vec2(31, 7), - level_mode: LevelMode::MipMap, - rounding_mode: RoundingMode::Down, - }, - - TileDescription { - tile_size: Vec2(0, 0), - level_mode: LevelMode::Singular, - rounding_mode: RoundingMode::Up, - }, - - TileDescription { - tile_size: Vec2(4294967294, 4294967295), - level_mode: LevelMode::RipMap, - rounding_mode: RoundingMode::Down, - }, - ]; - - for tile in &tiles { - let mut bytes = Vec::new(); - tile.write(&mut bytes).unwrap(); - - let new_tile = TileDescription::read(&mut Cursor::new(bytes)).unwrap(); - assert_eq!(*tile, new_tile, "tile round trip"); - } - } - - #[test] - fn attribute_write_read_roundtrip_and_byte_size(){ - let attributes = [ - ( - Text::from("greeting"), - AttributeValue::Text(Text::from("hello")), - ), - ( - Text::from("age"), - AttributeValue::I32(923), - ), - ( - Text::from("leg count"), - AttributeValue::F64(9.114939599234), - ), - ( - Text::from("rabbit area"), - AttributeValue::FloatRect(FloatRect { - min: Vec2(23.4234, 345.23), - max: Vec2(68623.0, 3.12425926538), - }), - ), - ( - Text::from("rabbit area int"), - AttributeValue::IntegerBounds(IntegerBounds { - position: Vec2(23, 345), - size: Vec2(68623, 3), - }), - ), - ( - Text::from("rabbit area int"), - AttributeValue::IntegerBounds(IntegerBounds { - position: Vec2(-(i32::MAX / 2 - 1), -(i32::MAX / 2 - 1)), - size: Vec2(i32::MAX as usize - 2, i32::MAX as usize - 2), - }), - ), - ( - Text::from("rabbit area int 2"), - AttributeValue::IntegerBounds(IntegerBounds { - position: Vec2(0, 0), - size: Vec2(i32::MAX as usize / 2 - 1, i32::MAX as usize / 2 - 1), - }), - ), - ( - Text::from("tests are difficult"), - AttributeValue::TextVector(vec![ - Text::from("sdoifjpsdv"), - Text::from("sdoifjpsdvxxxx"), - Text::from("sdoifjasd"), - Text::from("sdoifj"), - Text::from("sdoifjddddddddasdasd"), - ]), - ), - ( - Text::from("what should we eat tonight"), - AttributeValue::Preview(Preview { - size: Vec2(10, 30), - pixel_data: vec![31; 10 * 30 * 4], - }), - ), - ( - Text::from("leg count, again"), - AttributeValue::ChannelList(ChannelList::new(smallvec![ - ChannelDescription { - name: Text::from("Green"), - sample_type: SampleType::F16, - quantize_linearly: false, - sampling: Vec2(1,2) - }, - ChannelDescription { - name: Text::from("Red"), - sample_type: SampleType::F32, - quantize_linearly: true, - sampling: Vec2(1,2) - }, - ChannelDescription { - name: Text::from("Purple"), - sample_type: SampleType::U32, - quantize_linearly: false, - sampling: Vec2(0,0) - } - ], - )), - ), - ]; - - for (name, value) in &attributes { - let mut bytes = Vec::new(); - super::write(name.as_slice(), value, &mut bytes).unwrap(); - assert_eq!(super::byte_size(name, value), bytes.len(), "attribute.byte_size() for {:?}", (name, value)); - - let new_attribute = super::read(&mut PeekRead::new(Cursor::new(bytes)), 300).unwrap(); - assert_eq!((name.clone(), value.clone()), (new_attribute.0, new_attribute.1.unwrap()), "attribute round trip"); - } - - - { - let (name, value) = ( - Text::from("asdkaspfokpaosdkfpaokswdpoakpsfokaposdkf"), - AttributeValue::I32(0), - ); - - let mut long_names = false; - super::validate(&name, &value, &mut long_names, false, IntegerBounds::zero(), false).unwrap(); - assert!(long_names); - } - - { - let (name, value) = ( - Text::from("sdöksadöofkaspdolkpöasolfkcöalsod,kfcöaslodkcpöasolkfposdöksadöofkaspdolkpöasolfkcöalsod,kfcöaslodkcpöasolkfposdöksadöofkaspdolkpöasolfkcöalsod,kfcöaslodkcpöasolkfposdöksadöofkaspdolkpöasolfkcöalsod,kfcöaslodkcpöasolkfposdöksadöofkaspdolkpöasolfkcöalsod,kfcöaslodkcpöasolkfposdöksadöofkaspdolkpöasolfkcöalsod,kfcöaslodkcpöasolkfpo"), - AttributeValue::I32(0), - ); - - super::validate(&name, &value, &mut false, false, IntegerBounds::zero(), false).expect_err("name length check failed"); - } - } - - #[test] - fn time_code_pack(){ - let mut rng = thread_rng(); - - let codes = std::iter::repeat_with(|| TimeCode { - hours: rng.gen_range(0 .. 24), - minutes: rng.gen_range(0 .. 60), - seconds: rng.gen_range(0 .. 60), - frame: rng.gen_range(0 .. 29), - drop_frame: random(), - color_frame: random(), - field_phase: random(), - binary_group_flags: [random(),random(),random()], - binary_groups: std::iter::repeat_with(|| rng.gen_range(0 .. 16)).take(8) - .collect::>().into_inner().unwrap() - }); - - for code in codes.take(500) { - code.validate(true).expect("invalid timecode test input"); - - { // through tv60 packing, roundtrip - let packed_tv60 = code.pack_time_as_tv60_u32().expect("invalid timecode test input"); - let packed_user = code.pack_user_data_as_u32(); - assert_eq!(TimeCode::from_tv60_time(packed_tv60, packed_user), code); - } - - { // through bytes, roundtrip - let mut bytes = Vec::::new(); - code.write(&mut bytes).unwrap(); - let decoded = TimeCode::read(&mut bytes.as_slice()).unwrap(); - assert_eq!(code, decoded); - } - - { - let tv50_code = TimeCode { - drop_frame: false, // apparently, tv50 does not support drop frame, so do not use this value - .. code - }; - - let packed_tv50 = code.pack_time_as_tv50_u32().expect("invalid timecode test input"); - let packed_user = code.pack_user_data_as_u32(); - assert_eq!(TimeCode::from_tv50_time(packed_tv50, packed_user), tv50_code); - } - - { - let film24_code = TimeCode { - // apparently, film24 does not support some flags, so do not use those values - color_frame: false, - drop_frame: false, - .. code - }; - - let packed_film24 = code.pack_time_as_film24_u32().expect("invalid timecode test input"); - let packed_user = code.pack_user_data_as_u32(); - assert_eq!(TimeCode::from_film24_time(packed_film24, packed_user), film24_code); - } - } - } - -} -- cgit v1.2.3