use std::collections::{HashMap, HashSet}; use std::convert::TryFrom; use std::io::{self, Read, Seek}; use std::ops::Range; use crate::{ bytecast, ColorType, TiffError, TiffFormatError, TiffResult, TiffUnsupportedError, UsageError, }; use self::ifd::Directory; use self::image::Image; use crate::tags::{ CompressionMethod, PhotometricInterpretation, Predictor, SampleFormat, Tag, Type, }; use self::stream::{ByteOrder, EndianReader, SmartReader}; pub mod ifd; mod image; mod stream; mod tag_reader; /// Result of a decoding process #[derive(Debug)] pub enum DecodingResult { /// A vector of unsigned bytes U8(Vec), /// A vector of unsigned words U16(Vec), /// A vector of 32 bit unsigned ints U32(Vec), /// A vector of 64 bit unsigned ints U64(Vec), /// A vector of 32 bit IEEE floats F32(Vec), /// A vector of 64 bit IEEE floats F64(Vec), /// A vector of 8 bit signed ints I8(Vec), /// A vector of 16 bit signed ints I16(Vec), /// A vector of 32 bit signed ints I32(Vec), /// A vector of 64 bit signed ints I64(Vec), } impl DecodingResult { fn new_u8(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::U8(vec![0; size])) } } fn new_u16(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / 2 { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::U16(vec![0; size])) } } fn new_u32(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / 4 { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::U32(vec![0; size])) } } fn new_u64(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / 8 { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::U64(vec![0; size])) } } fn new_f32(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / std::mem::size_of::() { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::F32(vec![0.0; size])) } } fn new_f64(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / std::mem::size_of::() { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::F64(vec![0.0; size])) } } fn new_i8(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / std::mem::size_of::() { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::I8(vec![0; size])) } } fn new_i16(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / 2 { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::I16(vec![0; size])) } } fn new_i32(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / 4 { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::I32(vec![0; size])) } } fn new_i64(size: usize, limits: &Limits) -> TiffResult { if size > limits.decoding_buffer_size / 8 { Err(TiffError::LimitsExceeded) } else { Ok(DecodingResult::I64(vec![0; size])) } } pub fn as_buffer(&mut self, start: usize) -> DecodingBuffer { match *self { DecodingResult::U8(ref mut buf) => DecodingBuffer::U8(&mut buf[start..]), DecodingResult::U16(ref mut buf) => DecodingBuffer::U16(&mut buf[start..]), DecodingResult::U32(ref mut buf) => DecodingBuffer::U32(&mut buf[start..]), DecodingResult::U64(ref mut buf) => DecodingBuffer::U64(&mut buf[start..]), DecodingResult::F32(ref mut buf) => DecodingBuffer::F32(&mut buf[start..]), DecodingResult::F64(ref mut buf) => DecodingBuffer::F64(&mut buf[start..]), DecodingResult::I8(ref mut buf) => DecodingBuffer::I8(&mut buf[start..]), DecodingResult::I16(ref mut buf) => DecodingBuffer::I16(&mut buf[start..]), DecodingResult::I32(ref mut buf) => DecodingBuffer::I32(&mut buf[start..]), DecodingResult::I64(ref mut buf) => DecodingBuffer::I64(&mut buf[start..]), } } } // A buffer for image decoding pub enum DecodingBuffer<'a> { /// A slice of unsigned bytes U8(&'a mut [u8]), /// A slice of unsigned words U16(&'a mut [u16]), /// A slice of 32 bit unsigned ints U32(&'a mut [u32]), /// A slice of 64 bit unsigned ints U64(&'a mut [u64]), /// A slice of 32 bit IEEE floats F32(&'a mut [f32]), /// A slice of 64 bit IEEE floats F64(&'a mut [f64]), /// A slice of 8 bits signed ints I8(&'a mut [i8]), /// A slice of 16 bits signed ints I16(&'a mut [i16]), /// A slice of 32 bits signed ints I32(&'a mut [i32]), /// A slice of 64 bits signed ints I64(&'a mut [i64]), } impl<'a> DecodingBuffer<'a> { fn byte_len(&self) -> usize { match *self { DecodingBuffer::U8(_) => 1, DecodingBuffer::U16(_) => 2, DecodingBuffer::U32(_) => 4, DecodingBuffer::U64(_) => 8, DecodingBuffer::F32(_) => 4, DecodingBuffer::F64(_) => 8, DecodingBuffer::I8(_) => 1, DecodingBuffer::I16(_) => 2, DecodingBuffer::I32(_) => 4, DecodingBuffer::I64(_) => 8, } } fn copy<'b>(&'b mut self) -> DecodingBuffer<'b> where 'a: 'b, { match *self { DecodingBuffer::U8(ref mut buf) => DecodingBuffer::U8(buf), DecodingBuffer::U16(ref mut buf) => DecodingBuffer::U16(buf), DecodingBuffer::U32(ref mut buf) => DecodingBuffer::U32(buf), DecodingBuffer::U64(ref mut buf) => DecodingBuffer::U64(buf), DecodingBuffer::F32(ref mut buf) => DecodingBuffer::F32(buf), DecodingBuffer::F64(ref mut buf) => DecodingBuffer::F64(buf), DecodingBuffer::I8(ref mut buf) => DecodingBuffer::I8(buf), DecodingBuffer::I16(ref mut buf) => DecodingBuffer::I16(buf), DecodingBuffer::I32(ref mut buf) => DecodingBuffer::I32(buf), DecodingBuffer::I64(ref mut buf) => DecodingBuffer::I64(buf), } } fn subrange<'b>(&'b mut self, range: Range) -> DecodingBuffer<'b> where 'a: 'b, { match *self { DecodingBuffer::U8(ref mut buf) => DecodingBuffer::U8(&mut buf[range]), DecodingBuffer::U16(ref mut buf) => DecodingBuffer::U16(&mut buf[range]), DecodingBuffer::U32(ref mut buf) => DecodingBuffer::U32(&mut buf[range]), DecodingBuffer::U64(ref mut buf) => DecodingBuffer::U64(&mut buf[range]), DecodingBuffer::F32(ref mut buf) => DecodingBuffer::F32(&mut buf[range]), DecodingBuffer::F64(ref mut buf) => DecodingBuffer::F64(&mut buf[range]), DecodingBuffer::I8(ref mut buf) => DecodingBuffer::I8(&mut buf[range]), DecodingBuffer::I16(ref mut buf) => DecodingBuffer::I16(&mut buf[range]), DecodingBuffer::I32(ref mut buf) => DecodingBuffer::I32(&mut buf[range]), DecodingBuffer::I64(ref mut buf) => DecodingBuffer::I64(&mut buf[range]), } } fn as_bytes_mut(&mut self) -> &mut [u8] { match self { DecodingBuffer::U8(buf) => &mut *buf, DecodingBuffer::I8(buf) => bytecast::i8_as_ne_mut_bytes(buf), DecodingBuffer::U16(buf) => bytecast::u16_as_ne_mut_bytes(buf), DecodingBuffer::I16(buf) => bytecast::i16_as_ne_mut_bytes(buf), DecodingBuffer::U32(buf) => bytecast::u32_as_ne_mut_bytes(buf), DecodingBuffer::I32(buf) => bytecast::i32_as_ne_mut_bytes(buf), DecodingBuffer::U64(buf) => bytecast::u64_as_ne_mut_bytes(buf), DecodingBuffer::I64(buf) => bytecast::i64_as_ne_mut_bytes(buf), DecodingBuffer::F32(buf) => bytecast::f32_as_ne_mut_bytes(buf), DecodingBuffer::F64(buf) => bytecast::f64_as_ne_mut_bytes(buf), } } } #[derive(Debug, Copy, Clone, PartialEq)] /// Chunk type of the internal representation pub enum ChunkType { Strip, Tile, } /// Decoding limits #[derive(Clone, Debug)] pub struct Limits { /// The maximum size of any `DecodingResult` in bytes, the default is /// 256MiB. If the entire image is decoded at once, then this will /// be the maximum size of the image. If it is decoded one strip at a /// time, this will be the maximum size of a strip. pub decoding_buffer_size: usize, /// The maximum size of any ifd value in bytes, the default is /// 1MiB. pub ifd_value_size: usize, /// Maximum size for intermediate buffer which may be used to limit the amount of data read per /// segment even if the entire image is decoded at once. pub intermediate_buffer_size: usize, /// The purpose of this is to prevent all the fields of the struct from /// being public, as this would make adding new fields a major version /// bump. _non_exhaustive: (), } impl Limits { /// A configuration that does not impose any limits. /// /// This is a good start if the caller only wants to impose selective limits, contrary to the /// default limits which allows selectively disabling limits. /// /// Note that this configuration is likely to crash on excessively large images since, /// naturally, the machine running the program does not have infinite memory. pub fn unlimited() -> Limits { Limits { decoding_buffer_size: usize::max_value(), ifd_value_size: usize::max_value(), intermediate_buffer_size: usize::max_value(), _non_exhaustive: (), } } } impl Default for Limits { fn default() -> Limits { Limits { decoding_buffer_size: 256 * 1024 * 1024, intermediate_buffer_size: 128 * 1024 * 1024, ifd_value_size: 1024 * 1024, _non_exhaustive: (), } } } /// The representation of a TIFF decoder /// /// Currently does not support decoding of interlaced images #[derive(Debug)] pub struct Decoder where R: Read + Seek, { reader: SmartReader, bigtiff: bool, limits: Limits, next_ifd: Option, ifd_offsets: Vec, seen_ifds: HashSet, image: Image, } trait Wrapping { fn wrapping_add(&self, other: Self) -> Self; } impl Wrapping for u8 { fn wrapping_add(&self, other: Self) -> Self { u8::wrapping_add(*self, other) } } impl Wrapping for u16 { fn wrapping_add(&self, other: Self) -> Self { u16::wrapping_add(*self, other) } } impl Wrapping for u32 { fn wrapping_add(&self, other: Self) -> Self { u32::wrapping_add(*self, other) } } impl Wrapping for u64 { fn wrapping_add(&self, other: Self) -> Self { u64::wrapping_add(*self, other) } } impl Wrapping for i8 { fn wrapping_add(&self, other: Self) -> Self { i8::wrapping_add(*self, other) } } impl Wrapping for i16 { fn wrapping_add(&self, other: Self) -> Self { i16::wrapping_add(*self, other) } } impl Wrapping for i32 { fn wrapping_add(&self, other: Self) -> Self { i32::wrapping_add(*self, other) } } impl Wrapping for i64 { fn wrapping_add(&self, other: Self) -> Self { i64::wrapping_add(*self, other) } } fn rev_hpredict_nsamp(image: &mut [T], samples: usize) { for col in samples..image.len() { image[col] = image[col].wrapping_add(image[col - samples]); } } pub fn fp_predict_f32(input: &mut [u8], output: &mut [f32], samples: usize) { rev_hpredict_nsamp(input, samples); for i in 0..output.len() { // TODO: use f32::from_be_bytes() when we can (version 1.40) output[i] = f32::from_bits(u32::from_be_bytes([ input[input.len() / 4 * 0 + i], input[input.len() / 4 * 1 + i], input[input.len() / 4 * 2 + i], input[input.len() / 4 * 3 + i], ])); } } pub fn fp_predict_f64(input: &mut [u8], output: &mut [f64], samples: usize) { rev_hpredict_nsamp(input, samples); for i in 0..output.len() { // TODO: use f64::from_be_bytes() when we can (version 1.40) output[i] = f64::from_bits(u64::from_be_bytes([ input[input.len() / 8 * 0 + i], input[input.len() / 8 * 1 + i], input[input.len() / 8 * 2 + i], input[input.len() / 8 * 3 + i], input[input.len() / 8 * 4 + i], input[input.len() / 8 * 5 + i], input[input.len() / 8 * 6 + i], input[input.len() / 8 * 7 + i], ])); } } fn fix_endianness_and_predict( mut image: DecodingBuffer, samples: usize, byte_order: ByteOrder, predictor: Predictor, ) { match predictor { Predictor::None => { fix_endianness(&mut image, byte_order); } Predictor::Horizontal => { fix_endianness(&mut image, byte_order); match image { DecodingBuffer::U8(buf) => rev_hpredict_nsamp(buf, samples), DecodingBuffer::U16(buf) => rev_hpredict_nsamp(buf, samples), DecodingBuffer::U32(buf) => rev_hpredict_nsamp(buf, samples), DecodingBuffer::U64(buf) => rev_hpredict_nsamp(buf, samples), DecodingBuffer::I8(buf) => rev_hpredict_nsamp(buf, samples), DecodingBuffer::I16(buf) => rev_hpredict_nsamp(buf, samples), DecodingBuffer::I32(buf) => rev_hpredict_nsamp(buf, samples), DecodingBuffer::I64(buf) => rev_hpredict_nsamp(buf, samples), DecodingBuffer::F32(_) | DecodingBuffer::F64(_) => { unreachable!("Caller should have validated arguments. Please file a bug.") } } } Predictor::FloatingPoint => { let mut buffer_copy = image.as_bytes_mut().to_vec(); match image { DecodingBuffer::F32(buf) => fp_predict_f32(&mut buffer_copy, buf, samples), DecodingBuffer::F64(buf) => fp_predict_f64(&mut buffer_copy, buf, samples), _ => unreachable!("Caller should have validated arguments. Please file a bug."), } } } } fn invert_colors_unsigned(buffer: &mut [T], max: T) where T: std::ops::Sub + std::ops::Sub + Copy, { for datum in buffer.iter_mut() { *datum = max - *datum } } fn invert_colors_fp(buffer: &mut [T], max: T) where T: std::ops::Sub + std::ops::Sub + Copy, { for datum in buffer.iter_mut() { // FIXME: assumes [0, 1) range for floats *datum = max - *datum } } fn invert_colors(buf: &mut DecodingBuffer, color_type: ColorType) { match (color_type, buf) { (ColorType::Gray(64), DecodingBuffer::U64(ref mut buffer)) => { invert_colors_unsigned(buffer, 0xffff_ffff_ffff_ffff); } (ColorType::Gray(32), DecodingBuffer::U32(ref mut buffer)) => { invert_colors_unsigned(buffer, 0xffff_ffff); } (ColorType::Gray(16), DecodingBuffer::U16(ref mut buffer)) => { invert_colors_unsigned(buffer, 0xffff); } (ColorType::Gray(n), DecodingBuffer::U8(ref mut buffer)) if n <= 8 => { invert_colors_unsigned(buffer, 0xff); } (ColorType::Gray(32), DecodingBuffer::F32(ref mut buffer)) => { invert_colors_fp(buffer, 1.0); } (ColorType::Gray(64), DecodingBuffer::F64(ref mut buffer)) => { invert_colors_fp(buffer, 1.0); } _ => {} } } /// Fix endianness. If `byte_order` matches the host, then conversion is a no-op. fn fix_endianness(buf: &mut DecodingBuffer, byte_order: ByteOrder) { match byte_order { ByteOrder::LittleEndian => match buf { DecodingBuffer::U8(_) | DecodingBuffer::I8(_) => {} DecodingBuffer::U16(b) => b.iter_mut().for_each(|v| *v = u16::from_le(*v)), DecodingBuffer::I16(b) => b.iter_mut().for_each(|v| *v = i16::from_le(*v)), DecodingBuffer::U32(b) => b.iter_mut().for_each(|v| *v = u32::from_le(*v)), DecodingBuffer::I32(b) => b.iter_mut().for_each(|v| *v = i32::from_le(*v)), DecodingBuffer::U64(b) => b.iter_mut().for_each(|v| *v = u64::from_le(*v)), DecodingBuffer::I64(b) => b.iter_mut().for_each(|v| *v = i64::from_le(*v)), DecodingBuffer::F32(b) => b .iter_mut() .for_each(|v| *v = f32::from_bits(u32::from_le(v.to_bits()))), DecodingBuffer::F64(b) => b .iter_mut() .for_each(|v| *v = f64::from_bits(u64::from_le(v.to_bits()))), }, ByteOrder::BigEndian => match buf { DecodingBuffer::U8(_) | DecodingBuffer::I8(_) => {} DecodingBuffer::U16(b) => b.iter_mut().for_each(|v| *v = u16::from_be(*v)), DecodingBuffer::I16(b) => b.iter_mut().for_each(|v| *v = i16::from_be(*v)), DecodingBuffer::U32(b) => b.iter_mut().for_each(|v| *v = u32::from_be(*v)), DecodingBuffer::I32(b) => b.iter_mut().for_each(|v| *v = i32::from_be(*v)), DecodingBuffer::U64(b) => b.iter_mut().for_each(|v| *v = u64::from_be(*v)), DecodingBuffer::I64(b) => b.iter_mut().for_each(|v| *v = i64::from_be(*v)), DecodingBuffer::F32(b) => b .iter_mut() .for_each(|v| *v = f32::from_bits(u32::from_be(v.to_bits()))), DecodingBuffer::F64(b) => b .iter_mut() .for_each(|v| *v = f64::from_bits(u64::from_be(v.to_bits()))), }, }; } impl Decoder { /// Create a new decoder that decodes from the stream ```r``` pub fn new(mut r: R) -> TiffResult> { let mut endianess = Vec::with_capacity(2); (&mut r).take(2).read_to_end(&mut endianess)?; let byte_order = match &*endianess { b"II" => ByteOrder::LittleEndian, b"MM" => ByteOrder::BigEndian, _ => { return Err(TiffError::FormatError( TiffFormatError::TiffSignatureNotFound, )) } }; let mut reader = SmartReader::wrap(r, byte_order); let bigtiff = match reader.read_u16()? { 42 => false, 43 => { // Read bytesize of offsets (in bigtiff it's alway 8 but provide a way to move to 16 some day) if reader.read_u16()? != 8 { return Err(TiffError::FormatError( TiffFormatError::TiffSignatureNotFound, )); } // This constant should always be 0 if reader.read_u16()? != 0 { return Err(TiffError::FormatError( TiffFormatError::TiffSignatureNotFound, )); } true } _ => { return Err(TiffError::FormatError( TiffFormatError::TiffSignatureInvalid, )) } }; let next_ifd = if bigtiff { Some(reader.read_u64()?) } else { Some(u64::from(reader.read_u32()?)) }; let mut seen_ifds = HashSet::new(); seen_ifds.insert(*next_ifd.as_ref().unwrap()); let ifd_offsets = vec![*next_ifd.as_ref().unwrap()]; let mut decoder = Decoder { reader, bigtiff, limits: Default::default(), next_ifd, ifd_offsets, seen_ifds, image: Image { ifd: None, width: 0, height: 0, bits_per_sample: vec![1], samples: 1, sample_format: vec![SampleFormat::Uint], photometric_interpretation: PhotometricInterpretation::BlackIsZero, compression_method: CompressionMethod::None, jpeg_tables: None, predictor: Predictor::None, chunk_type: ChunkType::Strip, strip_decoder: None, tile_attributes: None, chunk_offsets: Vec::new(), chunk_bytes: Vec::new(), }, }; decoder.next_image()?; Ok(decoder) } pub fn with_limits(mut self, limits: Limits) -> Decoder { self.limits = limits; self } pub fn dimensions(&mut self) -> TiffResult<(u32, u32)> { Ok((self.image().width, self.image().height)) } pub fn colortype(&mut self) -> TiffResult { self.image().colortype() } fn image(&self) -> &Image { &self.image } /// Loads the IFD at the specified index in the list, if one exists pub fn seek_to_image(&mut self, ifd_index: usize) -> TiffResult<()> { // Check whether we have seen this IFD before, if so then the index will be less than the length of the list of ifd offsets if ifd_index >= self.ifd_offsets.len() { // We possibly need to load in the next IFD if self.next_ifd.is_none() { return Err(TiffError::FormatError( TiffFormatError::ImageFileDirectoryNotFound, )); } loop { // Follow the list until we find the one we want, or we reach the end, whichever happens first let (_ifd, next_ifd) = self.next_ifd()?; if next_ifd.is_none() { break; } if ifd_index < self.ifd_offsets.len() { break; } } } // If the index is within the list of ifds then we can load the selected image/IFD if let Some(ifd_offset) = self.ifd_offsets.get(ifd_index) { let (ifd, _next_ifd) = Self::read_ifd(&mut self.reader, self.bigtiff, *ifd_offset)?; self.image = Image::from_reader(&mut self.reader, ifd, &self.limits, self.bigtiff)?; Ok(()) } else { Err(TiffError::FormatError( TiffFormatError::ImageFileDirectoryNotFound, )) } } fn next_ifd(&mut self) -> TiffResult<(Directory, Option)> { if self.next_ifd.is_none() { return Err(TiffError::FormatError( TiffFormatError::ImageFileDirectoryNotFound, )); } let (ifd, next_ifd) = Self::read_ifd( &mut self.reader, self.bigtiff, self.next_ifd.take().unwrap(), )?; if let Some(next) = next_ifd { if !self.seen_ifds.insert(next) { return Err(TiffError::FormatError(TiffFormatError::CycleInOffsets)); } self.next_ifd = Some(next); self.ifd_offsets.push(next); } Ok((ifd, next_ifd)) } /// Reads in the next image. /// If there is no further image in the TIFF file a format error is returned. /// To determine whether there are more images call `TIFFDecoder::more_images` instead. pub fn next_image(&mut self) -> TiffResult<()> { let (ifd, _next_ifd) = self.next_ifd()?; self.image = Image::from_reader(&mut self.reader, ifd, &self.limits, self.bigtiff)?; Ok(()) } /// Returns `true` if there is at least one more image available. pub fn more_images(&self) -> bool { self.next_ifd.is_some() } /// Returns the byte_order pub fn byte_order(&self) -> ByteOrder { self.reader.byte_order } #[inline] pub fn read_ifd_offset(&mut self) -> Result { if self.bigtiff { self.read_long8() } else { self.read_long().map(u64::from) } } /// Reads a TIFF byte value #[inline] pub fn read_byte(&mut self) -> Result { let mut buf = [0; 1]; self.reader.read_exact(&mut buf)?; Ok(buf[0]) } /// Reads a TIFF short value #[inline] pub fn read_short(&mut self) -> Result { self.reader.read_u16() } /// Reads a TIFF sshort value #[inline] pub fn read_sshort(&mut self) -> Result { self.reader.read_i16() } /// Reads a TIFF long value #[inline] pub fn read_long(&mut self) -> Result { self.reader.read_u32() } /// Reads a TIFF slong value #[inline] pub fn read_slong(&mut self) -> Result { self.reader.read_i32() } /// Reads a TIFF float value #[inline] pub fn read_float(&mut self) -> Result { self.reader.read_f32() } /// Reads a TIFF double value #[inline] pub fn read_double(&mut self) -> Result { self.reader.read_f64() } #[inline] pub fn read_long8(&mut self) -> Result { self.reader.read_u64() } #[inline] pub fn read_slong8(&mut self) -> Result { self.reader.read_i64() } /// Reads a string #[inline] pub fn read_string(&mut self, length: usize) -> TiffResult { let mut out = vec![0; length]; self.reader.read_exact(&mut out)?; // Strings may be null-terminated, so we trim anything downstream of the null byte if let Some(first) = out.iter().position(|&b| b == 0) { out.truncate(first); } Ok(String::from_utf8(out)?) } /// Reads a TIFF IFA offset/value field #[inline] pub fn read_offset(&mut self) -> TiffResult<[u8; 4]> { if self.bigtiff { return Err(TiffError::FormatError( TiffFormatError::InconsistentSizesEncountered, )); } let mut val = [0; 4]; self.reader.read_exact(&mut val)?; Ok(val) } /// Reads a TIFF IFA offset/value field #[inline] pub fn read_offset_u64(&mut self) -> Result<[u8; 8], io::Error> { let mut val = [0; 8]; self.reader.read_exact(&mut val)?; Ok(val) } /// Moves the cursor to the specified offset #[inline] pub fn goto_offset(&mut self, offset: u32) -> io::Result<()> { self.goto_offset_u64(offset.into()) } #[inline] pub fn goto_offset_u64(&mut self, offset: u64) -> io::Result<()> { self.reader.seek(io::SeekFrom::Start(offset)).map(|_| ()) } /// Reads a IFD entry. // An IFD entry has four fields: // // Tag 2 bytes // Type 2 bytes // Count 4 bytes // Value 4 bytes either a pointer the value itself fn read_entry( reader: &mut SmartReader, bigtiff: bool, ) -> TiffResult> { let tag = Tag::from_u16_exhaustive(reader.read_u16()?); let type_ = match Type::from_u16(reader.read_u16()?) { Some(t) => t, None => { // Unknown type. Skip this entry according to spec. reader.read_u32()?; reader.read_u32()?; return Ok(None); } }; let entry = if bigtiff { let mut offset = [0; 8]; let count = reader.read_u64()?; reader.read_exact(&mut offset)?; ifd::Entry::new_u64(type_, count, offset) } else { let mut offset = [0; 4]; let count = reader.read_u32()?; reader.read_exact(&mut offset)?; ifd::Entry::new(type_, count, offset) }; Ok(Some((tag, entry))) } /// Reads the IFD starting at the indicated location. fn read_ifd( reader: &mut SmartReader, bigtiff: bool, ifd_location: u64, ) -> TiffResult<(Directory, Option)> { reader.goto_offset(ifd_location)?; let mut dir: Directory = HashMap::new(); let num_tags = if bigtiff { reader.read_u64()? } else { reader.read_u16()?.into() }; for _ in 0..num_tags { let (tag, entry) = match Self::read_entry(reader, bigtiff)? { Some(val) => val, None => { continue; } // Unknown data type in tag, skip }; dir.insert(tag, entry); } let next_ifd = if bigtiff { reader.read_u64()? } else { reader.read_u32()?.into() }; let next_ifd = match next_ifd { 0 => None, _ => Some(next_ifd), }; Ok((dir, next_ifd)) } /// Tries to retrieve a tag. /// Return `Ok(None)` if the tag is not present. pub fn find_tag(&mut self, tag: Tag) -> TiffResult> { let entry = match self.image().ifd.as_ref().unwrap().get(&tag) { None => return Ok(None), Some(entry) => entry.clone(), }; Ok(Some(entry.val( &self.limits, self.bigtiff, &mut self.reader, )?)) } /// Tries to retrieve a tag and convert it to the desired unsigned type. pub fn find_tag_unsigned>(&mut self, tag: Tag) -> TiffResult> { self.find_tag(tag)? .map(|v| v.into_u64()) .transpose()? .map(|value| { T::try_from(value).map_err(|_| TiffFormatError::InvalidTagValueType(tag).into()) }) .transpose() } /// Tries to retrieve a vector of all a tag's values and convert them to /// the desired unsigned type. pub fn find_tag_unsigned_vec>( &mut self, tag: Tag, ) -> TiffResult>> { self.find_tag(tag)? .map(|v| v.into_u64_vec()) .transpose()? .map(|v| { v.into_iter() .map(|u| { T::try_from(u).map_err(|_| TiffFormatError::InvalidTagValueType(tag).into()) }) .collect() }) .transpose() } /// Tries to retrieve a tag and convert it to the desired unsigned type. /// Returns an error if the tag is not present. pub fn get_tag_unsigned>(&mut self, tag: Tag) -> TiffResult { self.find_tag_unsigned(tag)? .ok_or_else(|| TiffFormatError::RequiredTagNotFound(tag).into()) } /// Tries to retrieve a tag. /// Returns an error if the tag is not present pub fn get_tag(&mut self, tag: Tag) -> TiffResult { match self.find_tag(tag)? { Some(val) => Ok(val), None => Err(TiffError::FormatError( TiffFormatError::RequiredTagNotFound(tag), )), } } /// Tries to retrieve a tag and convert it to the desired type. pub fn get_tag_u32(&mut self, tag: Tag) -> TiffResult { self.get_tag(tag)?.into_u32() } pub fn get_tag_u64(&mut self, tag: Tag) -> TiffResult { self.get_tag(tag)?.into_u64() } /// Tries to retrieve a tag and convert it to the desired type. pub fn get_tag_f32(&mut self, tag: Tag) -> TiffResult { self.get_tag(tag)?.into_f32() } /// Tries to retrieve a tag and convert it to the desired type. pub fn get_tag_f64(&mut self, tag: Tag) -> TiffResult { self.get_tag(tag)?.into_f64() } /// Tries to retrieve a tag and convert it to the desired type. pub fn get_tag_u32_vec(&mut self, tag: Tag) -> TiffResult> { self.get_tag(tag)?.into_u32_vec() } pub fn get_tag_u16_vec(&mut self, tag: Tag) -> TiffResult> { self.get_tag(tag)?.into_u16_vec() } pub fn get_tag_u64_vec(&mut self, tag: Tag) -> TiffResult> { self.get_tag(tag)?.into_u64_vec() } /// Tries to retrieve a tag and convert it to the desired type. pub fn get_tag_f32_vec(&mut self, tag: Tag) -> TiffResult> { self.get_tag(tag)?.into_f32_vec() } /// Tries to retrieve a tag and convert it to the desired type. pub fn get_tag_f64_vec(&mut self, tag: Tag) -> TiffResult> { self.get_tag(tag)?.into_f64_vec() } /// Tries to retrieve a tag and convert it to a 8bit vector. pub fn get_tag_u8_vec(&mut self, tag: Tag) -> TiffResult> { self.get_tag(tag)?.into_u8_vec() } /// Tries to retrieve a tag and convert it to a ascii vector. pub fn get_tag_ascii_string(&mut self, tag: Tag) -> TiffResult { self.get_tag(tag)?.into_string() } fn check_chunk_type(&self, expected: ChunkType) -> TiffResult<()> { if expected != self.image().chunk_type { return Err(TiffError::UsageError(UsageError::InvalidChunkType( expected, self.image().chunk_type, ))); } Ok(()) } /// The chunk type (Strips / Tiles) of the image pub fn get_chunk_type(&self) -> ChunkType { self.image().chunk_type } /// Number of strips in image pub fn strip_count(&mut self) -> TiffResult { self.check_chunk_type(ChunkType::Strip)?; let rows_per_strip = self.image().strip_decoder.as_ref().unwrap().rows_per_strip; if rows_per_strip == 0 { return Ok(0); } // rows_per_strip - 1 can never fail since we know it's at least 1 let height = match self.image().height.checked_add(rows_per_strip - 1) { Some(h) => h, None => return Err(TiffError::IntSizeError), }; Ok(height / rows_per_strip) } /// Number of tiles in image pub fn tile_count(&mut self) -> TiffResult { self.check_chunk_type(ChunkType::Tile)?; Ok(u32::try_from(self.image().chunk_offsets.len())?) } pub fn read_chunk_to_buffer( &mut self, mut buffer: DecodingBuffer, chunk_index: u32, output_width: usize, ) -> TiffResult<()> { let offset = self.image.chunk_file_range(chunk_index)?.0; self.goto_offset_u64(offset)?; let byte_order = self.reader.byte_order; self.image.expand_chunk( &mut self.reader, buffer.copy(), output_width, byte_order, chunk_index, )?; Ok(()) } fn result_buffer(&self, width: usize, height: usize) -> TiffResult { let buffer_size = match width .checked_mul(height) .and_then(|x| x.checked_mul(self.image().bits_per_sample.len())) { Some(s) => s, None => return Err(TiffError::LimitsExceeded), }; let max_sample_bits = self .image() .bits_per_sample .iter() .cloned() .max() .unwrap_or(8); match self .image() .sample_format .first() .unwrap_or(&SampleFormat::Uint) { SampleFormat::Uint => match max_sample_bits { n if n <= 8 => DecodingResult::new_u8(buffer_size, &self.limits), n if n <= 16 => DecodingResult::new_u16(buffer_size, &self.limits), n if n <= 32 => DecodingResult::new_u32(buffer_size, &self.limits), n if n <= 64 => DecodingResult::new_u64(buffer_size, &self.limits), n => Err(TiffError::UnsupportedError( TiffUnsupportedError::UnsupportedBitsPerChannel(n), )), }, SampleFormat::IEEEFP => match max_sample_bits { 32 => DecodingResult::new_f32(buffer_size, &self.limits), 64 => DecodingResult::new_f64(buffer_size, &self.limits), n => Err(TiffError::UnsupportedError( TiffUnsupportedError::UnsupportedBitsPerChannel(n), )), }, SampleFormat::Int => match max_sample_bits { n if n <= 8 => DecodingResult::new_i8(buffer_size, &self.limits), n if n <= 16 => DecodingResult::new_i16(buffer_size, &self.limits), n if n <= 32 => DecodingResult::new_i32(buffer_size, &self.limits), n if n <= 64 => DecodingResult::new_i64(buffer_size, &self.limits), n => Err(TiffError::UnsupportedError( TiffUnsupportedError::UnsupportedBitsPerChannel(n), )), }, format => { Err(TiffUnsupportedError::UnsupportedSampleFormat(vec![format.clone()]).into()) } } } /// Read the specified chunk (at index `chunk_index`) and return the binary data as a Vector. pub fn read_chunk(&mut self, chunk_index: u32) -> TiffResult { let data_dims = self.image().chunk_data_dimensions(chunk_index)?; let mut result = self.result_buffer(data_dims.0 as usize, data_dims.1 as usize)?; self.read_chunk_to_buffer(result.as_buffer(0), chunk_index, data_dims.0 as usize)?; Ok(result) } /// Returns the default chunk size for the current image. Any given chunk in the image is at most as large as /// the value returned here. For the size of the data (chunk minus padding), use `chunk_data_dimensions`. pub fn chunk_dimensions(&self) -> (u32, u32) { self.image().chunk_dimensions().unwrap() } /// Returns the size of the data in the chunk with the specified index. This is the default size of the chunk, /// minus any padding. pub fn chunk_data_dimensions(&self, chunk_index: u32) -> (u32, u32) { self.image() .chunk_data_dimensions(chunk_index) .expect("invalid chunk_index") } /// Decodes the entire image and return it as a Vector pub fn read_image(&mut self) -> TiffResult { let width = self.image().width; let height = self.image().height; let mut result = self.result_buffer(width as usize, height as usize)?; if width == 0 || height == 0 { return Ok(result); } let chunk_dimensions = self.image().chunk_dimensions()?; let chunk_dimensions = ( chunk_dimensions.0.min(width), chunk_dimensions.1.min(height), ); if chunk_dimensions.0 == 0 || chunk_dimensions.1 == 0 { return Err(TiffError::FormatError( TiffFormatError::InconsistentSizesEncountered, )); } let samples = self.image().bits_per_sample.len(); if samples == 0 { return Err(TiffError::FormatError( TiffFormatError::InconsistentSizesEncountered, )); } let chunks_across = ((width - 1) / chunk_dimensions.0 + 1) as usize; let strip_samples = width as usize * chunk_dimensions.1 as usize * samples; for chunk in 0..self.image().chunk_offsets.len() { self.goto_offset_u64(self.image().chunk_offsets[chunk])?; let x = chunk % chunks_across; let y = chunk / chunks_across; let buffer_offset = y * strip_samples + x * chunk_dimensions.0 as usize * samples; let byte_order = self.reader.byte_order; self.image.expand_chunk( &mut self.reader, result.as_buffer(buffer_offset).copy(), width as usize, byte_order, chunk as u32, )?; } Ok(result) } }