From 1b6a04ca5504955c571d1c97504fb45ea0befee4 Mon Sep 17 00:00:00 2001 From: Valentin Popov Date: Mon, 8 Jan 2024 01:21:28 +0400 Subject: Initial vendor packages Signed-off-by: Valentin Popov --- vendor/png/src/decoder/mod.rs | 961 ++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 961 insertions(+) create mode 100644 vendor/png/src/decoder/mod.rs (limited to 'vendor/png/src/decoder/mod.rs') diff --git a/vendor/png/src/decoder/mod.rs b/vendor/png/src/decoder/mod.rs new file mode 100644 index 0000000..09772fe --- /dev/null +++ b/vendor/png/src/decoder/mod.rs @@ -0,0 +1,961 @@ +mod stream; +mod zlib; + +pub use self::stream::{DecodeOptions, Decoded, DecodingError, StreamingDecoder}; +use self::stream::{FormatErrorInner, CHUNCK_BUFFER_SIZE}; + +use std::io::{BufRead, BufReader, Read}; +use std::mem; +use std::ops::Range; + +use crate::chunk; +use crate::common::{ + BitDepth, BytesPerPixel, ColorType, Info, ParameterErrorKind, Transformations, +}; +use crate::filter::{unfilter, FilterType}; +use crate::utils; + +/* +pub enum InterlaceHandling { + /// Outputs the raw rows + RawRows, + /// Fill missing the pixels from the existing ones + Rectangle, + /// Only fill the needed pixels + Sparkle +} +*/ + +/// Output info. +/// +/// This describes one particular frame of the image that was written into the output buffer. +#[derive(Debug, PartialEq, Eq)] +pub struct OutputInfo { + /// The pixel width of this frame. + pub width: u32, + /// The pixel height of this frame. + pub height: u32, + /// The chosen output color type. + pub color_type: ColorType, + /// The chosen output bit depth. + pub bit_depth: BitDepth, + /// The byte count of each scan line in the image. + pub line_size: usize, +} + +impl OutputInfo { + /// Returns the size needed to hold a decoded frame + /// If the output buffer was larger then bytes after this count should be ignored. They may + /// still have been changed. + pub fn buffer_size(&self) -> usize { + self.line_size * self.height as usize + } +} + +#[derive(Clone, Copy, Debug)] +/// Limits on the resources the `Decoder` is allowed too use +pub struct Limits { + /// maximum number of bytes the decoder is allowed to allocate, default is 64Mib + pub bytes: usize, +} + +impl Default for Limits { + fn default() -> Limits { + Limits { + bytes: 1024 * 1024 * 64, + } + } +} + +/// PNG Decoder +pub struct Decoder { + read_decoder: ReadDecoder, + /// Output transformations + transform: Transformations, + /// Limits on resources the Decoder is allowed to use + limits: Limits, +} + +/// A row of data with interlace information attached. +#[derive(Clone, Copy, Debug)] +pub struct InterlacedRow<'data> { + data: &'data [u8], + interlace: InterlaceInfo, +} + +impl<'data> InterlacedRow<'data> { + pub fn data(&self) -> &'data [u8] { + self.data + } + + pub fn interlace(&self) -> InterlaceInfo { + self.interlace + } +} + +/// PNG (2003) specifies two interlace modes, but reserves future extensions. +#[derive(Clone, Copy, Debug)] +pub enum InterlaceInfo { + /// the null method means no interlacing + Null, + /// Adam7 derives its name from doing 7 passes over the image, only decoding a subset of all pixels in each pass. + /// The following table shows pictorially what parts of each 8x8 area of the image is found in each pass: + /// + /// 1 6 4 6 2 6 4 6 + /// 7 7 7 7 7 7 7 7 + /// 5 6 5 6 5 6 5 6 + /// 7 7 7 7 7 7 7 7 + /// 3 6 4 6 3 6 4 6 + /// 7 7 7 7 7 7 7 7 + /// 5 6 5 6 5 6 5 6 + /// 7 7 7 7 7 7 7 7 + Adam7 { pass: u8, line: u32, width: u32 }, +} + +/// A row of data without interlace information. +#[derive(Clone, Copy, Debug)] +pub struct Row<'data> { + data: &'data [u8], +} + +impl<'data> Row<'data> { + pub fn data(&self) -> &'data [u8] { + self.data + } +} + +impl Decoder { + /// Create a new decoder configuration with default limits. + pub fn new(r: R) -> Decoder { + Decoder::new_with_limits(r, Limits::default()) + } + + /// Create a new decoder configuration with custom limits. + pub fn new_with_limits(r: R, limits: Limits) -> Decoder { + Decoder { + read_decoder: ReadDecoder { + reader: BufReader::with_capacity(CHUNCK_BUFFER_SIZE, r), + decoder: StreamingDecoder::new(), + at_eof: false, + }, + transform: Transformations::IDENTITY, + limits, + } + } + + /// Create a new decoder configuration with custom `DecodeOptions`. + pub fn new_with_options(r: R, decode_options: DecodeOptions) -> Decoder { + Decoder { + read_decoder: ReadDecoder { + reader: BufReader::with_capacity(CHUNCK_BUFFER_SIZE, r), + decoder: StreamingDecoder::new_with_options(decode_options), + at_eof: false, + }, + transform: Transformations::IDENTITY, + limits: Limits::default(), + } + } + + /// Limit resource usage. + /// + /// Note that your allocations, e.g. when reading into a pre-allocated buffer, are __NOT__ + /// considered part of the limits. Nevertheless, required intermediate buffers such as for + /// singular lines is checked against the limit. + /// + /// Note that this is a best-effort basis. + /// + /// ``` + /// use std::fs::File; + /// use png::{Decoder, Limits}; + /// // This image is 32×32, 1bit per pixel. The reader buffers one row which requires 4 bytes. + /// let mut limits = Limits::default(); + /// limits.bytes = 3; + /// let mut decoder = Decoder::new_with_limits(File::open("tests/pngsuite/basi0g01.png").unwrap(), limits); + /// assert!(decoder.read_info().is_err()); + /// + /// // This image is 32x32 pixels, so the decoder will allocate less than 10Kib + /// let mut limits = Limits::default(); + /// limits.bytes = 10*1024; + /// let mut decoder = Decoder::new_with_limits(File::open("tests/pngsuite/basi0g01.png").unwrap(), limits); + /// assert!(decoder.read_info().is_ok()); + /// ``` + pub fn set_limits(&mut self, limits: Limits) { + self.limits = limits; + } + + /// Read the PNG header and return the information contained within. + /// + /// Most image metadata will not be read until `read_info` is called, so those fields will be + /// None or empty. + pub fn read_header_info(&mut self) -> Result<&Info, DecodingError> { + let mut buf = Vec::new(); + while self.read_decoder.info().is_none() { + buf.clear(); + if self.read_decoder.decode_next(&mut buf)?.is_none() { + return Err(DecodingError::Format( + FormatErrorInner::UnexpectedEof.into(), + )); + } + } + Ok(self.read_decoder.info().unwrap()) + } + + /// Reads all meta data until the first IDAT chunk + pub fn read_info(mut self) -> Result, DecodingError> { + self.read_header_info()?; + + let mut reader = Reader { + decoder: self.read_decoder, + bpp: BytesPerPixel::One, + subframe: SubframeInfo::not_yet_init(), + fctl_read: 0, + next_frame: SubframeIdx::Initial, + prev: Vec::new(), + current: Vec::new(), + scan_start: 0, + transform: self.transform, + scratch_buffer: Vec::new(), + limits: self.limits, + }; + + // Check if the decoding buffer of a single raw line has a valid size. + if reader.info().checked_raw_row_length().is_none() { + return Err(DecodingError::LimitsExceeded); + } + + // Check if the output buffer has a valid size. + let (width, height) = reader.info().size(); + let (color, depth) = reader.output_color_type(); + let rowlen = color + .checked_raw_row_length(depth, width) + .ok_or(DecodingError::LimitsExceeded)? + - 1; + let height: usize = + std::convert::TryFrom::try_from(height).map_err(|_| DecodingError::LimitsExceeded)?; + if rowlen.checked_mul(height).is_none() { + return Err(DecodingError::LimitsExceeded); + } + + reader.read_until_image_data()?; + Ok(reader) + } + + /// Set the allowed and performed transformations. + /// + /// A transformation is a pre-processing on the raw image data modifying content or encoding. + /// Many options have an impact on memory or CPU usage during decoding. + pub fn set_transformations(&mut self, transform: Transformations) { + self.transform = transform; + } + + /// Set the decoder to ignore all text chunks while parsing. + /// + /// eg. + /// ``` + /// use std::fs::File; + /// use png::Decoder; + /// let mut decoder = Decoder::new(File::open("tests/pngsuite/basi0g01.png").unwrap()); + /// decoder.set_ignore_text_chunk(true); + /// assert!(decoder.read_info().is_ok()); + /// ``` + pub fn set_ignore_text_chunk(&mut self, ignore_text_chunk: bool) { + self.read_decoder + .decoder + .set_ignore_text_chunk(ignore_text_chunk); + } + + /// Set the decoder to ignore and not verify the Adler-32 checksum + /// and CRC code. + pub fn ignore_checksums(&mut self, ignore_checksums: bool) { + self.read_decoder + .decoder + .set_ignore_adler32(ignore_checksums); + self.read_decoder.decoder.set_ignore_crc(ignore_checksums); + } +} + +struct ReadDecoder { + reader: BufReader, + decoder: StreamingDecoder, + at_eof: bool, +} + +impl ReadDecoder { + /// Returns the next decoded chunk. If the chunk is an ImageData chunk, its contents are written + /// into image_data. + fn decode_next(&mut self, image_data: &mut Vec) -> Result, DecodingError> { + while !self.at_eof { + let (consumed, result) = { + let buf = self.reader.fill_buf()?; + if buf.is_empty() { + return Err(DecodingError::Format( + FormatErrorInner::UnexpectedEof.into(), + )); + } + self.decoder.update(buf, image_data)? + }; + self.reader.consume(consumed); + match result { + Decoded::Nothing => (), + Decoded::ImageEnd => self.at_eof = true, + result => return Ok(Some(result)), + } + } + Ok(None) + } + + fn finish_decoding(&mut self) -> Result<(), DecodingError> { + while !self.at_eof { + let buf = self.reader.fill_buf()?; + if buf.is_empty() { + return Err(DecodingError::Format( + FormatErrorInner::UnexpectedEof.into(), + )); + } + let (consumed, event) = self.decoder.update(buf, &mut vec![])?; + self.reader.consume(consumed); + match event { + Decoded::Nothing => (), + Decoded::ImageEnd => self.at_eof = true, + // ignore more data + Decoded::ChunkComplete(_, _) | Decoded::ChunkBegin(_, _) | Decoded::ImageData => {} + Decoded::ImageDataFlushed => return Ok(()), + Decoded::PartialChunk(_) => {} + new => unreachable!("{:?}", new), + } + } + + Err(DecodingError::Format( + FormatErrorInner::UnexpectedEof.into(), + )) + } + + fn info(&self) -> Option<&Info> { + self.decoder.info.as_ref() + } +} + +/// PNG reader (mostly high-level interface) +/// +/// Provides a high level that iterates over lines or whole images. +pub struct Reader { + decoder: ReadDecoder, + bpp: BytesPerPixel, + subframe: SubframeInfo, + /// Number of frame control chunks read. + /// By the APNG specification the total number must equal the count specified in the animation + /// control chunk. The IDAT image _may_ have such a chunk applying to it. + fctl_read: u32, + next_frame: SubframeIdx, + /// Previous raw line + prev: Vec, + /// Current raw line + current: Vec, + /// Start index of the current scan line. + scan_start: usize, + /// Output transformations + transform: Transformations, + /// This buffer is only used so that `next_row` and `next_interlaced_row` can return reference + /// to a byte slice. In a future version of this library, this buffer will be removed and + /// `next_row` and `next_interlaced_row` will write directly into a user provided output buffer. + scratch_buffer: Vec, + /// How resources we can spend (for example, on allocation). + limits: Limits, +} + +/// The subframe specific information. +/// +/// In APNG the frames are constructed by combining previous frame and a new subframe (through a +/// combination of `dispose_op` and `overlay_op`). These sub frames specify individual dimension +/// information and reuse the global interlace options. This struct encapsulates the state of where +/// in a particular IDAT-frame or subframe we are. +struct SubframeInfo { + width: u32, + height: u32, + rowlen: usize, + interlace: InterlaceIter, + consumed_and_flushed: bool, +} + +#[derive(Clone)] +enum InterlaceIter { + None(Range), + Adam7(utils::Adam7Iterator), +} + +/// Denote a frame as given by sequence numbers. +#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord)] +enum SubframeIdx { + /// The initial frame in an IDAT chunk without fcTL chunk applying to it. + /// Note that this variant precedes `Some` as IDAT frames precede fdAT frames and all fdAT + /// frames must have a fcTL applying to it. + Initial, + /// An IDAT frame with fcTL or an fdAT frame. + Some(u32), + /// The past-the-end index. + End, +} + +impl Reader { + /// Reads all meta data until the next frame data starts. + /// Requires IHDR before the IDAT and fcTL before fdAT. + fn read_until_image_data(&mut self) -> Result<(), DecodingError> { + loop { + // This is somewhat ugly. The API requires us to pass a buffer to decode_next but we + // know that we will stop before reading any image data from the stream. Thus pass an + // empty buffer and assert that remains empty. + let mut buf = Vec::new(); + let state = self.decoder.decode_next(&mut buf)?; + assert!(buf.is_empty()); + + match state { + Some(Decoded::ChunkBegin(_, chunk::IDAT)) + | Some(Decoded::ChunkBegin(_, chunk::fdAT)) => break, + Some(Decoded::FrameControl(_)) => { + self.subframe = SubframeInfo::new(self.info()); + // The next frame is the one to which this chunk applies. + self.next_frame = SubframeIdx::Some(self.fctl_read); + // TODO: what about overflow here? That would imply there are more fctl chunks + // than can be specified in the animation control but also that we have read + // several gigabytes of data. + self.fctl_read += 1; + } + None => { + return Err(DecodingError::Format( + FormatErrorInner::MissingImageData.into(), + )) + } + // Ignore all other chunk events. Any other chunk may be between IDAT chunks, fdAT + // chunks and their control chunks. + _ => {} + } + } + + let info = self + .decoder + .info() + .ok_or(DecodingError::Format(FormatErrorInner::MissingIhdr.into()))?; + self.bpp = info.bpp_in_prediction(); + self.subframe = SubframeInfo::new(info); + + // Allocate output buffer. + let buflen = self.output_line_size(self.subframe.width); + if buflen > self.limits.bytes { + return Err(DecodingError::LimitsExceeded); + } + + self.prev.clear(); + self.prev.resize(self.subframe.rowlen, 0); + + Ok(()) + } + + /// Get information on the image. + /// + /// The structure will change as new frames of an animated image are decoded. + pub fn info(&self) -> &Info { + self.decoder.info().unwrap() + } + + /// Decodes the next frame into `buf`. + /// + /// Note that this decodes raw subframes that need to be mixed according to blend-op and + /// dispose-op by the caller. + /// + /// The caller must always provide a buffer large enough to hold a complete frame (the APNG + /// specification restricts subframes to the dimensions given in the image header). The region + /// that has been written be checked afterwards by calling `info` after a successful call and + /// inspecting the `frame_control` data. This requirement may be lifted in a later version of + /// `png`. + /// + /// Output lines will be written in row-major, packed matrix with width and height of the read + /// frame (or subframe), all samples are in big endian byte order where this matters. + pub fn next_frame(&mut self, buf: &mut [u8]) -> Result { + let subframe_idx = match self.decoder.info().unwrap().frame_control() { + None => SubframeIdx::Initial, + Some(_) => SubframeIdx::Some(self.fctl_read - 1), + }; + + if self.next_frame == SubframeIdx::End { + return Err(DecodingError::Parameter( + ParameterErrorKind::PolledAfterEndOfImage.into(), + )); + } else if self.next_frame != subframe_idx { + // Advance until we've read the info / fcTL for this frame. + self.read_until_image_data()?; + } + + if buf.len() < self.output_buffer_size() { + return Err(DecodingError::Parameter( + ParameterErrorKind::ImageBufferSize { + expected: buf.len(), + actual: self.output_buffer_size(), + } + .into(), + )); + } + + let (color_type, bit_depth) = self.output_color_type(); + let output_info = OutputInfo { + width: self.subframe.width, + height: self.subframe.height, + color_type, + bit_depth, + line_size: self.output_line_size(self.subframe.width), + }; + + self.current.clear(); + self.scan_start = 0; + let width = self.info().width; + if self.info().interlaced { + while let Some(InterlacedRow { + data: row, + interlace, + .. + }) = self.next_interlaced_row()? + { + let (line, pass) = match interlace { + InterlaceInfo::Adam7 { line, pass, .. } => (line, pass), + InterlaceInfo::Null => unreachable!("expected interlace information"), + }; + let samples = color_type.samples() as u8; + utils::expand_pass(buf, width, row, pass, line, samples * (bit_depth as u8)); + } + } else { + for row in buf + .chunks_exact_mut(output_info.line_size) + .take(self.subframe.height as usize) + { + self.next_interlaced_row_impl(self.subframe.rowlen, row)?; + } + } + + // Advance over the rest of data for this (sub-)frame. + if !self.subframe.consumed_and_flushed { + self.decoder.finish_decoding()?; + } + + // Advance our state to expect the next frame. + let past_end_subframe = self + .info() + .animation_control() + .map(|ac| ac.num_frames) + .unwrap_or(0); + self.next_frame = match self.next_frame { + SubframeIdx::End => unreachable!("Next frame called when already at image end"), + // Reached the end of non-animated image. + SubframeIdx::Initial if past_end_subframe == 0 => SubframeIdx::End, + // An animated image, expecting first subframe. + SubframeIdx::Initial => SubframeIdx::Some(0), + // This was the last subframe, slightly fuzzy condition in case of programmer error. + SubframeIdx::Some(idx) if past_end_subframe <= idx + 1 => SubframeIdx::End, + // Expecting next subframe. + SubframeIdx::Some(idx) => SubframeIdx::Some(idx + 1), + }; + + Ok(output_info) + } + + /// Returns the next processed row of the image + pub fn next_row(&mut self) -> Result, DecodingError> { + self.next_interlaced_row() + .map(|v| v.map(|v| Row { data: v.data })) + } + + /// Returns the next processed row of the image + pub fn next_interlaced_row(&mut self) -> Result, DecodingError> { + let (rowlen, interlace) = match self.next_pass() { + Some((rowlen, interlace)) => (rowlen, interlace), + None => return Ok(None), + }; + + let width = if let InterlaceInfo::Adam7 { width, .. } = interlace { + width + } else { + self.subframe.width + }; + let output_line_size = self.output_line_size(width); + + // TODO: change the interface of `next_interlaced_row` to take an output buffer instead of + // making us return a reference to a buffer that we own. + let mut output_buffer = mem::take(&mut self.scratch_buffer); + output_buffer.resize(output_line_size, 0u8); + let ret = self.next_interlaced_row_impl(rowlen, &mut output_buffer); + self.scratch_buffer = output_buffer; + ret?; + + Ok(Some(InterlacedRow { + data: &self.scratch_buffer[..output_line_size], + interlace, + })) + } + + /// Fetch the next interlaced row and filter it according to our own transformations. + fn next_interlaced_row_impl( + &mut self, + rowlen: usize, + output_buffer: &mut [u8], + ) -> Result<(), DecodingError> { + self.next_raw_interlaced_row(rowlen)?; + let row = &self.prev[1..rowlen]; + + // Apply transformations and write resulting data to buffer. + let (color_type, bit_depth, trns) = { + let info = self.info(); + ( + info.color_type, + info.bit_depth as u8, + info.trns.is_some() || self.transform.contains(Transformations::ALPHA), + ) + }; + let expand = self.transform.contains(Transformations::EXPAND) + || self.transform.contains(Transformations::ALPHA); + let strip16 = bit_depth == 16 && self.transform.contains(Transformations::STRIP_16); + let info = self.decoder.info().unwrap(); + let trns = if trns { + Some(info.trns.as_deref()) + } else { + None + }; + match (color_type, trns) { + (ColorType::Indexed, _) if expand => { + output_buffer[..row.len()].copy_from_slice(row); + expand_paletted(output_buffer, info, trns)?; + } + (ColorType::Grayscale | ColorType::GrayscaleAlpha, _) if bit_depth < 8 && expand => { + output_buffer[..row.len()].copy_from_slice(row); + expand_gray_u8(output_buffer, info, trns) + } + (ColorType::Grayscale | ColorType::Rgb, Some(trns)) if expand => { + let channels = color_type.samples(); + if bit_depth == 8 { + utils::expand_trns_line(row, output_buffer, trns, channels); + } else if strip16 { + utils::expand_trns_and_strip_line16(row, output_buffer, trns, channels); + } else { + assert_eq!(bit_depth, 16); + utils::expand_trns_line16(row, output_buffer, trns, channels); + } + } + ( + ColorType::Grayscale | ColorType::GrayscaleAlpha | ColorType::Rgb | ColorType::Rgba, + _, + ) if strip16 => { + for i in 0..row.len() / 2 { + output_buffer[i] = row[2 * i]; + } + } + _ => output_buffer.copy_from_slice(row), + } + + Ok(()) + } + + /// Returns the color type and the number of bits per sample + /// of the data returned by `Reader::next_row` and Reader::frames`. + pub fn output_color_type(&self) -> (ColorType, BitDepth) { + use crate::common::ColorType::*; + let t = self.transform; + let info = self.info(); + if t == Transformations::IDENTITY { + (info.color_type, info.bit_depth) + } else { + let bits = match info.bit_depth as u8 { + 16 if t.intersects(Transformations::STRIP_16) => 8, + n if n < 8 + && (t.contains(Transformations::EXPAND) + || t.contains(Transformations::ALPHA)) => + { + 8 + } + n => n, + }; + let color_type = + if t.contains(Transformations::EXPAND) || t.contains(Transformations::ALPHA) { + let has_trns = info.trns.is_some() || t.contains(Transformations::ALPHA); + match info.color_type { + Grayscale if has_trns => GrayscaleAlpha, + Rgb if has_trns => Rgba, + Indexed if has_trns => Rgba, + Indexed => Rgb, + ct => ct, + } + } else { + info.color_type + }; + (color_type, BitDepth::from_u8(bits).unwrap()) + } + } + + /// Returns the number of bytes required to hold a deinterlaced image frame + /// that is decoded using the given input transformations. + pub fn output_buffer_size(&self) -> usize { + let (width, height) = self.info().size(); + let size = self.output_line_size(width); + size * height as usize + } + + /// Returns the number of bytes required to hold a deinterlaced row. + pub fn output_line_size(&self, width: u32) -> usize { + let (color, depth) = self.output_color_type(); + color.raw_row_length_from_width(depth, width) - 1 + } + + fn next_pass(&mut self) -> Option<(usize, InterlaceInfo)> { + match self.subframe.interlace { + InterlaceIter::Adam7(ref mut adam7) => { + let last_pass = adam7.current_pass(); + let (pass, line, width) = adam7.next()?; + let rowlen = self.info().raw_row_length_from_width(width); + if last_pass != pass { + self.prev.clear(); + self.prev.resize(rowlen, 0u8); + } + Some((rowlen, InterlaceInfo::Adam7 { pass, line, width })) + } + InterlaceIter::None(ref mut height) => { + let _ = height.next()?; + Some((self.subframe.rowlen, InterlaceInfo::Null)) + } + } + } + + /// Write the next raw interlaced row into `self.prev`. + /// + /// The scanline is filtered against the previous scanline according to the specification. + fn next_raw_interlaced_row(&mut self, rowlen: usize) -> Result<(), DecodingError> { + // Read image data until we have at least one full row (but possibly more than one). + while self.current.len() - self.scan_start < rowlen { + if self.subframe.consumed_and_flushed { + return Err(DecodingError::Format( + FormatErrorInner::NoMoreImageData.into(), + )); + } + + // Clear the current buffer before appending more data. + if self.scan_start > 0 { + self.current.drain(..self.scan_start).for_each(drop); + self.scan_start = 0; + } + + match self.decoder.decode_next(&mut self.current)? { + Some(Decoded::ImageData) => {} + Some(Decoded::ImageDataFlushed) => { + self.subframe.consumed_and_flushed = true; + } + None => { + return Err(DecodingError::Format( + if self.current.is_empty() { + FormatErrorInner::NoMoreImageData + } else { + FormatErrorInner::UnexpectedEndOfChunk + } + .into(), + )); + } + _ => (), + } + } + + // Get a reference to the current row and point scan_start to the next one. + let row = &mut self.current[self.scan_start..]; + self.scan_start += rowlen; + + // Unfilter the row. + let filter = FilterType::from_u8(row[0]).ok_or(DecodingError::Format( + FormatErrorInner::UnknownFilterMethod(row[0]).into(), + ))?; + unfilter(filter, self.bpp, &self.prev[1..rowlen], &mut row[1..rowlen]); + + // Save the current row for the next pass. + self.prev[..rowlen].copy_from_slice(&row[..rowlen]); + + Ok(()) + } +} + +impl SubframeInfo { + fn not_yet_init() -> Self { + SubframeInfo { + width: 0, + height: 0, + rowlen: 0, + interlace: InterlaceIter::None(0..0), + consumed_and_flushed: false, + } + } + + fn new(info: &Info) -> Self { + // The apng fctnl overrides width and height. + // All other data is set by the main info struct. + let (width, height) = if let Some(fc) = info.frame_control { + (fc.width, fc.height) + } else { + (info.width, info.height) + }; + + let interlace = if info.interlaced { + InterlaceIter::Adam7(utils::Adam7Iterator::new(width, height)) + } else { + InterlaceIter::None(0..height) + }; + + SubframeInfo { + width, + height, + rowlen: info.raw_row_length_from_width(width), + interlace, + consumed_and_flushed: false, + } + } +} + +fn expand_paletted( + buffer: &mut [u8], + info: &Info, + trns: Option>, +) -> Result<(), DecodingError> { + if let Some(palette) = info.palette.as_ref() { + if let BitDepth::Sixteen = info.bit_depth { + // This should have been caught earlier but let's check again. Can't hurt. + Err(DecodingError::Format( + FormatErrorInner::InvalidColorBitDepth { + color_type: ColorType::Indexed, + bit_depth: BitDepth::Sixteen, + } + .into(), + )) + } else { + let black = [0, 0, 0]; + if let Some(trns) = trns { + let trns = trns.unwrap_or(&[]); + // > The tRNS chunk shall not contain more alpha values than there are palette + // entries, but a tRNS chunk may contain fewer values than there are palette + // entries. In this case, the alpha value for all remaining palette entries is + // assumed to be 255. + // + // It seems, accepted reading is to fully *ignore* an invalid tRNS as if it were + // completely empty / all pixels are non-transparent. + let trns = if trns.len() <= palette.len() / 3 { + trns + } else { + &[] + }; + + utils::unpack_bits(buffer, 4, info.bit_depth as u8, |i, chunk| { + let (rgb, a) = ( + palette + .get(3 * i as usize..3 * i as usize + 3) + .unwrap_or(&black), + *trns.get(i as usize).unwrap_or(&0xFF), + ); + chunk[0] = rgb[0]; + chunk[1] = rgb[1]; + chunk[2] = rgb[2]; + chunk[3] = a; + }); + } else { + utils::unpack_bits(buffer, 3, info.bit_depth as u8, |i, chunk| { + let rgb = palette + .get(3 * i as usize..3 * i as usize + 3) + .unwrap_or(&black); + chunk[0] = rgb[0]; + chunk[1] = rgb[1]; + chunk[2] = rgb[2]; + }) + } + Ok(()) + } + } else { + Err(DecodingError::Format( + FormatErrorInner::PaletteRequired.into(), + )) + } +} + +fn expand_gray_u8(buffer: &mut [u8], info: &Info, trns: Option>) { + let rescale = true; + let scaling_factor = if rescale { + (255) / ((1u16 << info.bit_depth as u8) - 1) as u8 + } else { + 1 + }; + if let Some(trns) = trns { + utils::unpack_bits(buffer, 2, info.bit_depth as u8, |pixel, chunk| { + chunk[1] = if let Some(trns) = trns { + if pixel == trns[0] { + 0 + } else { + 0xFF + } + } else { + 0xFF + }; + chunk[0] = pixel * scaling_factor + }) + } else { + utils::unpack_bits(buffer, 1, info.bit_depth as u8, |val, chunk| { + chunk[0] = val * scaling_factor + }) + } +} + +#[cfg(test)] +mod tests { + use super::Decoder; + use std::io::{BufRead, Read, Result}; + use std::mem::discriminant; + + /// A reader that reads at most `n` bytes. + struct SmalBuf { + inner: R, + cap: usize, + } + + impl SmalBuf { + fn new(inner: R, cap: usize) -> Self { + SmalBuf { inner, cap } + } + } + + impl Read for SmalBuf { + fn read(&mut self, buf: &mut [u8]) -> Result { + let len = buf.len().min(self.cap); + self.inner.read(&mut buf[..len]) + } + } + + impl BufRead for SmalBuf { + fn fill_buf(&mut self) -> Result<&[u8]> { + let buf = self.inner.fill_buf()?; + let len = buf.len().min(self.cap); + Ok(&buf[..len]) + } + + fn consume(&mut self, amt: usize) { + assert!(amt <= self.cap); + self.inner.consume(amt) + } + } + + #[test] + fn no_data_dup_on_finish() { + const IMG: &[u8] = include_bytes!(concat!( + env!("CARGO_MANIFEST_DIR"), + "/tests/bugfixes/x_issue#214.png" + )); + + let mut normal = Decoder::new(IMG).read_info().unwrap(); + + let mut buffer = vec![0; normal.output_buffer_size()]; + let normal = normal.next_frame(&mut buffer).unwrap_err(); + + let smal = Decoder::new(SmalBuf::new(IMG, 1)) + .read_info() + .unwrap() + .next_frame(&mut buffer) + .unwrap_err(); + + assert_eq!(discriminant(&normal), discriminant(&smal)); + } +} -- cgit v1.2.3