PDF4QT/Pdf4QtLib/sources/pdfjbig2decoder.h
2021-08-10 19:22:56 +02:00

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21 KiB
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// Copyright (C) 2019-2021 Jakub Melka
//
// This file is part of PDF4QT.
//
// PDF4QT is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// with the written consent of the copyright owner, any later version.
//
// PDF4QT is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with PDF4QT. If not, see <https://www.gnu.org/licenses/>.
#ifndef PDFJBIG2DECODER_H
#define PDFJBIG2DECODER_H
#include "pdfutils.h"
#include "pdfcolorspaces.h"
#include <optional>
namespace pdf
{
class PDFJBIG2Bitmap;
class PDFRenderErrorReporter;
class PDFJBIG2HuffmanCodeTable;
class PDFJBIG2SymbolDictionary;
class PDFJBIG2PatternDictionary;
struct PDFJBIG2HuffmanTableEntry;
struct PDFJBIG2BitmapDecodingParameters;
struct PDFJBIG2TextRegionDecodingParameters;
struct PDFJBIG2BitmapRefinementDecodingParameters;
enum class PDFJBIG2BitOperation
{
Invalid,
Or,
And,
Xor,
NotXor,
Replace
};
struct PDFJBIG2HuffmanTableEntry
{
enum class Type : uint8_t
{
Standard,
Negative,
OutOfBand
};
/// Returns true, if current row represents interval (-∞, value),
/// it means 32bit number must be read and
bool isLowValue() const { return type == Type::Negative; }
/// Returns true, if current row represents out-of-band value
bool isOutOfBand() const { return type == Type::OutOfBand; }
int32_t value = 0; ///< Base value
uint16_t prefixBitLength = 0; ///< Bit length of prefix
uint16_t rangeBitLength = 0; ///< Bit length of additional value
uint16_t prefix = 0; ///< Bit prefix of the huffman code
Type type = Type::Standard; ///< Type of the value
};
/// Arithmetic decoder state for JBIG2 data streams. It contains state for context,
/// state is stored as 8-bit value, where only 7 bits are used. 6 bits are used
/// to store Qe value index (current row in the table, number 0-46), and lowest 1 bit
/// is used to store current MPS value (most probable symbol - 0/1).
class PDF4QTLIBSHARED_EXPORT PDFJBIG2ArithmeticDecoderState
{
public:
explicit inline PDFJBIG2ArithmeticDecoderState() = default;
explicit inline PDFJBIG2ArithmeticDecoderState(size_t size) :
m_state(size, 0)
{
}
/// Resets the context
inline void reset(const uint8_t bits)
{
size_t size = (1ULL << bits);
std::fill(m_state.begin(), m_state.end(), 0);
if (m_state.size() != size)
{
m_state.resize(size, 0);
}
}
/// Resets the context using another context
inline void reset(const uint8_t bits, const PDFJBIG2ArithmeticDecoderState& other)
{
reset(bits);
const size_t size = qMin(m_state.size(), other.m_state.size());
std::copy(other.m_state.begin(), other.m_state.begin() + size, m_state.begin());
}
/// Returns row index to Qe value table, according to document ISO/IEC 14492:2001,
/// annex E, table E.1 (Qe values and probability estimation process).
inline uint8_t getQeRowIndex(size_t context) const
{
Q_ASSERT(context < m_state.size());
return m_state[context] >> 1;
}
/// Returns Qe value for row index, according to document ISO/IEC 14492:2001,
/// annex E, table E.1 (Qe values and probability estimation process).
inline uint32_t getQe(size_t context) const;
/// Returns current bit value of MPS (most probable symbol)
inline uint8_t getMPS(size_t context) const
{
Q_ASSERT(context < m_state.size());
return m_state[context] & 0x1;
}
/// Sets current row index to Qe value table, at given context, and also MPS bit value
/// (most probable symbol).
inline void setQeRowIndexAndMPS(size_t context, uint8_t QeRowIndex, uint8_t MPS)
{
Q_ASSERT(context < m_state.size());
Q_ASSERT(MPS < 2);
m_state[context] = (QeRowIndex << 1) + MPS;
}
private:
std::vector<uint8_t> m_state;
};
/// Arithmetic decoder for JBIG2 data streams. This arithmetic decoder is implementation
/// of decoder described in document ISO/IEC 14492:2001, T.88, annex G (arithmetic decoding
/// procedure). It uses 32-bit fixed point arithmetic instead of 16-bit fixed point
/// arithmetic described in the specification (it is much faster).
class PDF4QTLIBSHARED_EXPORT PDFJBIG2ArithmeticDecoder
{
public:
explicit inline PDFJBIG2ArithmeticDecoder(PDFBitReader* reader) :
m_c(0),
m_a(0),
m_ct(0),
m_lastByte(0),
m_reader(reader)
{
}
void initialize() { perform_INITDEC(); }
uint32_t readBit(size_t context, PDFJBIG2ArithmeticDecoderState* state) { return perform_DECODE(context, state); }
uint32_t readByte(size_t context, PDFJBIG2ArithmeticDecoderState* state);
uint32_t getRegisterC() const { return m_c; }
uint32_t getRegisterA() const { return m_a; }
uint32_t getRegisterCT() const { return m_ct; }
int32_t getIAID(uint32_t size, PDFJBIG2ArithmeticDecoderState* state);
std::optional<int32_t> getSignedInteger(PDFJBIG2ArithmeticDecoderState* state);
/// This function is used to read last byte of byte sequence { 0xFF, 0xAC },
/// when finishing data stream.
void finalize();
private:
/// Performs INITDEC operation as described in the specification
void perform_INITDEC();
/// Performs BYTEIN operation as described in the specification
void perform_BYTEIN();
/// Performs DECODE operation as described in the specification
/// \param context Context index
/// \param state State of the arithmetic decoder
/// \returns Single decoded bit (lowest bit, other bits are zero)
uint32_t perform_DECODE(size_t context, PDFJBIG2ArithmeticDecoderState* state);
/// This is 32 bit register consisting of two 16-bit subregisters - "c_high" and "c_low", as
/// it is in specification. But we can work with it as 32 bit register (if we adjust some
/// operations and fixed point arithmetic).
uint32_t m_c;
/// This is 32 bit register for interval range. In the specification, it is 16-bit register,
/// but we use 32-bit fixed point arithmetic instead of 16-bit fixed point arithmetic.
uint32_t m_a;
/// Number of current unprocessed bits.
uint32_t m_ct;
/// Last processed byte
uint8_t m_lastByte;
/// Data source to read from
PDFBitReader* m_reader;
};
enum class JBIG2SegmentType : uint32_t
{
Invalid,
SymbolDictionary, ///< See chapter 7.4.2 in specification
TextRegion, ///< See chapter 7.4.3 in specification
PatternDictionary, ///< See chapter 7.4.4 in specification
HalftoneRegion, ///< See chapter 7.4.5 in specification
GenericRegion, ///< See chapter 7.4.6 in specification
GenericRefinementRegion, ///< See chapter 7.4.7 in specification
PageInformation, ///< See chapter 7.4.8 in specification
EndOfPage, ///< See chapter 7.4.9 in specification
EndOfStripe, ///< See chapter 7.4.10 in specification
EndOfFile, ///< See chapter 7.4.11 in specification
Profiles, ///< See chapter 7.4.12 in specification
Tables, ///< See chapter 7.4.13 in specification
Extension ///< See chapter 7.4.14 in specification
};
class PDFJBIG2SegmentHeader
{
public:
explicit inline PDFJBIG2SegmentHeader() = default;
/// Returns segment type
inline JBIG2SegmentType getSegmentType() const { return m_segmentType; }
/// Returns segment number
inline uint32_t getSegmentNumber() const { return m_segmentNumber; }
/// Returns segment data length (or 0xFFFFFFFF, if length is not defined)
/// \sa isSegmentDataLengthDefined
inline uint32_t getSegmentDataLength() const { return m_segmentDataLength; }
/// Returns true, if segment is immediate (direct paint on page's bitmap)
inline bool isImmediate() const { return m_immediate; }
/// Returns true, if segment is lossless
inline bool isLossless() const { return m_lossless; }
/// Returns true, if segmend data length is defined
inline bool isSegmentDataLengthDefined() const { return m_segmentDataLength != 0xFFFFFFFF; }
/// Returns referred segments
inline const std::vector<uint32_t>& getReferredSegments() const { return m_referredSegments; }
/// Reads the segment header from the data stream. If error occurs, then
/// exception is thrown.
static PDFJBIG2SegmentHeader read(PDFBitReader* reader);
private:
uint32_t m_segmentNumber = 0;
uint32_t m_pageAssociation = 0;
uint32_t m_segmentDataLength = 0;
JBIG2SegmentType m_segmentType = JBIG2SegmentType::Invalid;
bool m_immediate = false;
bool m_lossless = false;
std::vector<uint32_t> m_referredSegments;
};
class PDFJBIG2Segment
{
public:
explicit inline PDFJBIG2Segment() = default;
virtual ~PDFJBIG2Segment();
virtual const PDFJBIG2Bitmap* asBitmap() const { return nullptr; }
virtual PDFJBIG2Bitmap* asBitmap() { return nullptr; }
virtual const PDFJBIG2HuffmanCodeTable* asHuffmanCodeTable() const { return nullptr; }
virtual PDFJBIG2HuffmanCodeTable* asHuffmanCodeTable() { return nullptr; }
virtual const PDFJBIG2SymbolDictionary* asSymbolDictionary() const { return nullptr; }
virtual PDFJBIG2SymbolDictionary* asSymbolDictionary() { return nullptr; }
virtual const PDFJBIG2PatternDictionary* asPatternDictionary() const { return nullptr; }
virtual PDFJBIG2PatternDictionary* asPatternDictionary() { return nullptr; }
};
/// Huffman decoder - can decode integers / out of band values from huffman table.
class PDFJBIG2HuffmanDecoder
{
public:
explicit inline PDFJBIG2HuffmanDecoder() = default;
/// Constructs huffman decoder from static tables, so no memory are allocated (vector is empty)
explicit inline PDFJBIG2HuffmanDecoder(PDFBitReader* reader, const PDFJBIG2HuffmanTableEntry* begin, const PDFJBIG2HuffmanTableEntry* end) :
m_reader(reader),
m_begin(begin),
m_end(end)
{
}
/// Constructs huffman decoder from huffman code table, in this case, memory is allocated
explicit PDFJBIG2HuffmanDecoder(PDFBitReader* reader, const PDFJBIG2HuffmanCodeTable* table);
/// Constructs huffman decoder from huffman code table, in this case, memory is allocated
explicit PDFJBIG2HuffmanDecoder(PDFBitReader* reader, std::vector<PDFJBIG2HuffmanTableEntry>&& table);
PDFJBIG2HuffmanDecoder(const PDFJBIG2HuffmanDecoder&) = delete;
PDFJBIG2HuffmanDecoder(PDFJBIG2HuffmanDecoder&& other);
PDFJBIG2HuffmanDecoder& operator=(const PDFJBIG2HuffmanDecoder&) = delete;
PDFJBIG2HuffmanDecoder& operator=(PDFJBIG2HuffmanDecoder&& other);
/// Returns true, if huffman table is valid (and usable)
bool isValid() const { return m_begin != m_end; }
/// Returns true, if huffman table has out-of-band value
bool isOutOfBandSupported() const;
/// Tries to read signed integer using the table and current reader.
/// \returns Integer, or out-of-band value, using the std::optional semantics
std::optional<int32_t> readSignedInteger();
private:
/// Data source to read from
PDFBitReader* m_reader = nullptr;
const PDFJBIG2HuffmanTableEntry* m_begin = nullptr;
const PDFJBIG2HuffmanTableEntry* m_end = nullptr;
std::vector<PDFJBIG2HuffmanTableEntry> m_entries;
};
class PDF4QTLIBSHARED_EXPORT PDFJBIG2Bitmap : public PDFJBIG2Segment
{
public:
explicit PDFJBIG2Bitmap();
explicit PDFJBIG2Bitmap(int width, int height);
explicit PDFJBIG2Bitmap(int width, int height, uint8_t fill);
virtual ~PDFJBIG2Bitmap() override;
virtual const PDFJBIG2Bitmap* asBitmap() const override { return this; }
virtual PDFJBIG2Bitmap* asBitmap() override { return this; }
inline int getWidth() const { return m_width; }
inline int getHeight() const { return m_height; }
inline int getPixelCount() const { return m_width * m_height; }
inline uint8_t getPixel(int x, int y) const { return m_data[y * m_width + x]; }
inline void setPixel(int x, int y, uint8_t value) { m_data[y * m_width + x] = value; }
inline uint8_t getPixelSafe(int x, int y) const
{
if (x < 0 || x >= m_width || y < 0 || y >= m_height)
{
return 0;
}
return getPixel(x, y);
}
inline void fill(uint8_t value) { std::fill(m_data.begin(), m_data.end(), value); }
inline void fillZero() { fill(0); }
inline void fillOne() { fill(0xFF); }
inline bool isValid() const { return getPixelCount() > 0; }
/// Returns subbitmap of this bitmap. If some pixels of subbitmap are outside
/// of current bitmap, then they are reset to zero.
/// \param offsetX Horizontal offset of subbitmap
/// \param offsetY Vertical offset of subbitmap
/// \param width Width of subbitmap
/// \param height Height of subbitmap
PDFJBIG2Bitmap getSubbitmap(int offsetX, int offsetY, int width, int height) const;
/// Paints another bitmap onto this bitmap. If bitmap is invalid, nothing is done.
/// If \p expandY is true, height of target bitmap is expanded to fit source draw area.
/// \param bitmap Bitmap to be painted on this
/// \param offsetX Horizontal offset of paint area
/// \param offsetY Vertical offset of paint area
/// \param operation Paint operation to be performed
/// \param expandY Expand vertically, if painted bitmap exceeds current bitmap area
/// \param expandPixel Initialize pixels by this value during expanding
void paint(const PDFJBIG2Bitmap& bitmap, int offsetX, int offsetY, PDFJBIG2BitOperation operation, bool expandY, const uint8_t expandPixel);
/// Copies data from source row to target row. If source or target row doesn't exists,
/// then exception is thrown.
/// \param target Target row
/// \param source Source row
void copyRow(int target, int source);
private:
int m_width;
int m_height;
std::vector<uint8_t> m_data;
};
struct PDFJBIG2ReferencedSegments
{
std::vector<const PDFJBIG2Bitmap*> bitmaps;
std::vector<const PDFJBIG2HuffmanCodeTable*> codeTables;
std::vector<const PDFJBIG2SymbolDictionary*> symbolDictionaries;
std::vector<const PDFJBIG2PatternDictionary*> patternDictionaries;
size_t currentUserCodeTableIndex = 0;
/// Returns symbol bitmaps from all symbol dictionaries
std::vector<const PDFJBIG2Bitmap*> getSymbolBitmaps() const;
/// Returns pattern bitmaps from all pattern dictionaries
std::vector<const PDFJBIG2Bitmap*> getPatternBitmaps() const;
/// Returns current user huffman table according the index. If index
/// is out of range, then exception is thrown.
PDFJBIG2HuffmanDecoder getUserTable(PDFBitReader* reader);
};
/// Region segment information field, see chapter 7.4.1 in the specification
struct PDFJBIG2RegionSegmentInformationField
{
uint32_t width = 0;
uint32_t height = 0;
int32_t offsetX = 0;
int32_t offsetY = 0;
PDFJBIG2BitOperation operation = PDFJBIG2BitOperation::Invalid;
};
/// Info structure for adaptative template
struct PDFJBIG2ATPosition
{
int8_t x = 0;
int8_t y = 0;
};
using PDFJBIG2ATPositions = std::array<PDFJBIG2ATPosition, 4>;
/// Decoder of JBIG2 data streams. Decodes the black/white monochrome image.
/// Handles also global segments. Decoder decodes data using the specification
/// ISO/IEC 14492:2001, T.88.
class PDF4QTLIBSHARED_EXPORT PDFJBIG2Decoder
{
public:
explicit inline PDFJBIG2Decoder(QByteArray data, QByteArray globalData, PDFRenderErrorReporter* errorReporter) :
m_data(qMove(data)),
m_globalData(qMove(globalData)),
m_errorReporter(errorReporter),
m_reader(nullptr, 8),
m_pageDefaultPixelValue(0),
m_pageDefaultCompositionOperator(PDFJBIG2BitOperation::Invalid),
m_pageDefaultCompositionOperatorOverriden(false),
m_pageSizeUndefined(false)
{
}
PDFJBIG2Decoder(const PDFJBIG2Decoder&) = delete;
PDFJBIG2Decoder(PDFJBIG2Decoder&&) = default;
PDFJBIG2Decoder& operator=(const PDFJBIG2Decoder&) = delete;
PDFJBIG2Decoder& operator=(PDFJBIG2Decoder&&) = default;
~PDFJBIG2Decoder();
/// Decodes image interpreting the data as JBIG2 data stream. If image cannot
/// be decoded, exception is thrown (or invalid PDFImageData is returned).
/// \param maskingType Image masking type
PDFImageData decode(PDFImageData::MaskingType maskingType);
/// Decodes image interpreting the data as JBIG2 file stream (not data stream).
/// Decoding procedure also handles file header/file flags and number of pages.
/// If number of pages is invalid, then exception is thrown.
PDFImageData decodeFileStream();
private:
static constexpr const uint32_t MAX_BITMAP_SIZE = 65536;
/// Processes current data stream (reads all data from the stream, interprets
/// them as segments and processes the segments).
void processStream();
void processSymbolDictionary(const PDFJBIG2SegmentHeader& header);
void processTextRegion(const PDFJBIG2SegmentHeader& header);
void processPatternDictionary(const PDFJBIG2SegmentHeader& header);
void processHalftoneRegion(const PDFJBIG2SegmentHeader& header);
void processGenericRegion(const PDFJBIG2SegmentHeader& header);
void processGenericRefinementRegion(const PDFJBIG2SegmentHeader& header);
void processPageInformation(const PDFJBIG2SegmentHeader& header);
void processEndOfPage(const PDFJBIG2SegmentHeader& header);
void processEndOfStripe(const PDFJBIG2SegmentHeader& header);
void processEndOfFile(const PDFJBIG2SegmentHeader& header);
void processProfiles(const PDFJBIG2SegmentHeader& header);
void processCodeTables(const PDFJBIG2SegmentHeader& header);
void processExtension(const PDFJBIG2SegmentHeader& header);
/// Returns bitmap for given segment index. If bitmap is not found, or segment
/// is of different type, then exception is thrown.
/// \param segmentIndex Segment index with bitmap
/// \param remove Remove the segment?
PDFJBIG2Bitmap getBitmap(const uint32_t segmentIndex, bool remove);
/// Reads bitmap using decoding parameters
/// \param parameters Decoding parameters
PDFJBIG2Bitmap readBitmap(PDFJBIG2BitmapDecodingParameters& parameters);
/// Reads refined bitmap using decoding parameters
/// \param parameters Decoding parameters
PDFJBIG2Bitmap readRefinementBitmap(PDFJBIG2BitmapRefinementDecodingParameters& parameters);
/// Reads text bitmap using decoding parameters
/// \param parameters Decoding parameters
PDFJBIG2Bitmap readTextBitmap(PDFJBIG2TextRegionDecodingParameters& parameters);
/// Reads the region segment information field (see chapter 7.4.1)
PDFJBIG2RegionSegmentInformationField readRegionSegmentInformationField();
/// Read adaptative pixel template positions, positions, which are not read, are filled with 0
PDFJBIG2ATPositions readATTemplatePixelPositions(int count);
/// Skip segment data
void skipSegment(const PDFJBIG2SegmentHeader& header);
/// Returns structure containing referenced segments. If segment numbers
/// are wrong, or invalid segments appears, then exception is thrown.
/// \param header Header, from which referred segments are read
PDFJBIG2ReferencedSegments getReferencedSegments(const PDFJBIG2SegmentHeader& header) const;
static void checkBitmapSize(const uint32_t size);
static void checkRegionSegmentInformationField(const PDFJBIG2RegionSegmentInformationField& field);
static int32_t checkInteger(std::optional<int32_t> value);
QByteArray m_data;
QByteArray m_globalData;
PDFRenderErrorReporter* m_errorReporter;
PDFBitReader m_reader;
std::map<uint32_t, std::unique_ptr<PDFJBIG2Segment>> m_segments;
uint8_t m_pageDefaultPixelValue;
PDFJBIG2BitOperation m_pageDefaultCompositionOperator;
bool m_pageDefaultCompositionOperatorOverriden;
bool m_pageSizeUndefined;
PDFJBIG2Bitmap m_pageBitmap;
};
} // namespace pdf
#endif // PDFJBIG2DECODER_H