// Copyright (C) 2019-2020 Jakub Melka
//
// This file is part of PdfForQt.
//
// PdfForQt 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
// (at your option) any later version.
//
// PdfForQt 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 PDFForQt. If not, see <https://www.gnu.org/licenses/>.
#ifndef PDFUTILS_H
#define PDFUTILS_H
#include "pdfglobal.h"
#include <QRectF>
#include <QColor>
#include <QByteArray>
#include <QDataStream>
#include <vector>
#include <iterator>
#include <functional>
namespace pdf
{
/// Class for easy storing of cached item. This class is not thread safe,
/// and for this reason, access function are not constant (they can modify the
/// object).
template<typename T>
class PDFCachedItem
{
public:
explicit inline PDFCachedItem() :
m_dirty(true),
m_object()
{
}
/// Returns the cached object. If object is dirty, then cached object is refreshed.
/// \param holder Holder object, which owns the cached item
/// \param function Refresh function
template<typename H>
inline const T& get(const H* holder, T(H::* function)(void) const)
{
if (m_dirty)
{
m_object = (holder->*function)();
m_dirty = false;
}
return m_object;
}
/// Returns the cached object. If object is dirty, then cached object is refreshed.
/// \param holder Holder object, which owns the cached item
/// \param function Refresh function
template<typename H>
inline const T& get(H* holder, T(H::* function)(void))
{
if (m_dirty)
{
m_object = (holder->*function)();
m_dirty = false;
}
return m_object;
}
/// Returns the cached object. If object is dirty, then cached object is refreshed.
/// \param function Refresh function
inline const T& get(const std::function<T(void)>& function)
{
if (m_dirty)
{
m_object = function();
m_dirty = false;
}
return m_object;
}
/// Invalidates the cached item, so it must be refreshed from the cache next time,
/// if it is accessed.
inline void dirty()
{
m_dirty = true;
m_object = T();
}
private:
bool m_dirty;
T m_object;
};
/// Bit-reader, which can read n-bit unsigned integers from the stream.
/// Number of bits can be set in the constructor and is constant.
class PDFFORQTLIBSHARED_EXPORT PDFBitReader
{
public:
using Value = uint64_t;
explicit PDFBitReader(const QByteArray* stream, Value bitsPerComponent);
PDFBitReader(const PDFBitReader&) = default;
PDFBitReader(PDFBitReader&&) = default;
PDFBitReader& operator=(const PDFBitReader&) = default;
PDFBitReader& operator=(PDFBitReader&&) = default;
/// Returns maximal value of n-bit unsigned integer.
Value max() const { return m_maximalValue; }
/// Reads single n-bit value from the stream. If stream hasn't enough data,
/// then exception is thrown.
Value read() { return read(m_bitsPerComponent); }
/// Reads single n-bit value from the stream. If stream hasn't enough data,
/// then exception is thrown.
Value read(Value bits);
/// Reads single n-bit value from the stream. If stream hasn't enough data,
/// then exception is thrown. State of the stream is not changed, i.e., read
/// bits are reverted back.
Value look(Value bits) const;
/// Seeks the desired position in the data stream. If position can't be seeked,
/// then exception is thrown.
void seek(qint64 position);
/// Skips desired number of bytes
void skipBytes(Value bytes);
/// Seeks data to the byte boundary (number of processed bits is divisible by 8)
void alignToBytes();
/// Returns true, if we are at the end of the data stream (no more data can be read)
bool isAtEnd() const;
/// Returns position in the data stream (byte position, not bit position, so
/// result of this function is sometimes inaccurate)
int getPosition() const { return m_position; }
/// Reads signed 32-bit integer from the stream
int32_t readSignedInt();
/// Reads signed 8-bit integer from the stream
int8_t readSignedByte();
/// Reads unsigned 32-bit integer from the stream
uint32_t readUnsignedInt() { return read(32); }
/// Reads unsigned 16-bit integer from the stream
uint16_t readUnsignedWord() { return read(16); }
/// Reads unsigned 8-bit integer from the stream
uint8_t readUnsignedByte() { return read(8); }
/// Return underlying byte stream
const QByteArray* getStream() const { return m_stream; }
/// Reads substream from current stream. This function works only on byte boundary,
/// otherwise exception is thrown.
/// \param length Length of the substream. Can be -1, in this case, all remaining data is read.
QByteArray readSubstream(int length);
private:
const QByteArray* m_stream;
int m_position;
Value m_bitsPerComponent;
Value m_maximalValue;
Value m_buffer;
Value m_bitsInBuffer;
};
/// Bit writer
class PDFBitWriter
{
public:
using Value = uint64_t;
explicit PDFBitWriter(Value bitsPerComponent);
/// Writes value to the output stream
void write(Value value);
/// Finish line - align to byte boundary
void finishLine() { flush(true); }
/// Returns the result byte array
QByteArray takeByteArray() { return qMove(m_outputByteArray); }
/// Reserve memory in buffer
void reserve(int size) { m_outputByteArray.reserve(size); }
private:
void flush(bool alignToByteBoundary);
QByteArray m_outputByteArray;
Value m_bitsPerComponent;
Value m_mask;
Value m_buffer;
Value m_bitsInBuffer;
};
/// Simple class guard, for properly saving/restoring new/old value. In the constructor,
/// new value is stored in the pointer (old one is being saved), and in the destructor,
/// old value is restored. This object assumes, that value is not a null pointer.
template<typename Value>
class PDFTemporaryValueChange
{
public:
/// Constructor
/// \param value Value pointer (must not be a null pointer)
/// \param newValue New value to be set to the pointer
explicit inline PDFTemporaryValueChange(Value* valuePointer, Value newValue) :
m_oldValue(qMove(*valuePointer)),
m_value(valuePointer)
{
*valuePointer = qMove(newValue);
}
inline ~PDFTemporaryValueChange()
{
*m_value = qMove(m_oldValue);
}
private:
Value m_oldValue;
Value* m_value;
};
/// Implements range for range based for cycles
template<typename T>
class PDFIntegerRange
{
public:
explicit inline constexpr PDFIntegerRange(T begin, T end) : m_begin(begin), m_end(end) { }
struct Iterator : public std::iterator<std::random_access_iterator_tag, T, ptrdiff_t, T*, T&>
{
inline Iterator() : value(T(0)) { }
inline Iterator(T value) : value(value) { }
inline bool operator==(const Iterator& other) const { return value == other.value; }
inline bool operator!=(const Iterator& other) const { return value != other.value; }
inline T operator*() const { return value; }
inline Iterator& operator+=(ptrdiff_t movement) { value += T(movement); return *this; }
inline Iterator& operator-=(ptrdiff_t movement) { value -= T(movement); return *this; }
inline Iterator operator+(ptrdiff_t movement) const { return Iterator(value + T(movement)); }
inline ptrdiff_t operator-(const Iterator& other) const { return ptrdiff_t(value - other.value); }
inline Iterator& operator++()
{
++value;
return *this;
}
inline Iterator operator++(int)
{
Iterator copy(*this);
++value;
return copy;
}
inline Iterator& operator--()
{
--value;
return *this;
}
inline Iterator operator--(int)
{
Iterator copy(*this);
--value;
return copy;
}
T value = 0;
};
Iterator begin() const { return Iterator(m_begin); }
Iterator end() const { return Iterator(m_end); }
private:
T m_begin;
T m_end;
};
template<typename T>
bool contains(T value, std::initializer_list<T> list)
{
return (std::find(list.begin(), list.end(), value) != list.end());
}
/// Performs linear mapping of value x in interval [x_min, x_max] to the interval [y_min, y_max].
/// \param x Value to be linearly remapped from interval [x_min, x_max] to the interval [y_min, y_max].
/// \param x_min Start of the input interval
/// \param x_max End of the input interval
/// \param y_min Start of the output interval
/// \param y_max End of the output interval
static inline constexpr PDFReal interpolate(PDFReal x, PDFReal x_min, PDFReal x_max, PDFReal y_min, PDFReal y_max)
{
return y_min + (x - x_min) * (y_max - y_min) / (x_max - x_min);
}
inline
std::vector<uint8_t> convertByteArrayToVector(const QByteArray& data)
{
return std::vector<uint8_t>(reinterpret_cast<const uint8_t*>(data.constData()), reinterpret_cast<const uint8_t*>(data.constData()) + data.size());
}
inline
const unsigned char* convertByteArrayToUcharPtr(const QByteArray& data)
{
return reinterpret_cast<const unsigned char*>(data.constData());
}
inline
unsigned char* convertByteArrayToUcharPtr(QByteArray& data)
{
return reinterpret_cast<unsigned char*>(data.data());
}
/// This function computes ceil of log base 2 of value. The algorithm is taken
/// from: http://graphics.stanford.edu/~seander/bithacks.html#IntegerLogDeBruijn.
/// License for this function is public domain.
inline constexpr uint8_t log2ceil(uint32_t value)
{
const uint32_t originalValue = value;
constexpr uint8_t MULTIPLY_DE_BRUIJN_BIT_POSITION[32] =
{
0, 9, 1, 10, 13, 21, 2, 29, 11, 14, 16, 18, 22, 25, 3, 30,
8, 12, 20, 28, 15, 17, 24, 7, 19, 27, 23, 6, 26, 5, 4, 31
};
value |= value >> 1;
value |= value >> 2;
value |= value >> 4;
value |= value >> 8;
value |= value >> 16;
uint8_t logarithm = MULTIPLY_DE_BRUIJN_BIT_POSITION[static_cast<uint32_t>((value * 0x07C4ACDDU) >> 27)];
// Ceil
if ((1U << logarithm) < originalValue)
{
++logarithm;
}
return logarithm;
}
struct PDFFORQTLIBSHARED_EXPORT PDFDependentLibraryInfo
{
Q_DECLARE_TR_FUNCTIONS(pdf::PDFDependentLibraryInfo)
public:
QString library;
QString version;
QString license;
QString url;
static std::vector<PDFDependentLibraryInfo> getLibraryInfo();
};
/// Union-find algorithm, which uses path compression optimization. It can run in time
/// O(n + f * (1 + log(n)/log(2 + f/n)), where n is number of unions (resp. size of the
/// array) and f is number of find operations.
template<typename T>
class PDFUnionFindAlgorithm
{
public:
explicit PDFUnionFindAlgorithm(T size)
{
m_indices.resize(size, T(0));
std::iota(m_indices.begin(), m_indices.end(), 0);
}
T find(T index)
{
// Use path compression optimization. We assume we will not
// have long paths, so we will use simple recursion and
// not while cycle.
if (m_indices[index] != index)
{
m_indices[index] = find(m_indices[index]);
}
return m_indices[index];
}
void unify(T x, T y)
{
T xRoot = find(x);
T yRoot = find(y);
if (xRoot < yRoot)
{
m_indices[yRoot] = xRoot;
}
else if (xRoot > yRoot)
{
m_indices[xRoot] = yRoot;
}
}
private:
std::vector<T> m_indices;
};
template<typename T>
constexpr bool isIntervalOverlap(T x1_min, T x1_max, T x2_min, T x2_max)
{
// We have two situations, where intervals doesn't overlap:
// 1) |--------| |---------|
// x1_min x1_max x2_min x2_max
// 2) |--------| |---------|
// x2_min x2_max x1_min x1_max
if (x1_max < x2_min || x2_max < x1_min)
{
return false;
}
return true;
}
constexpr bool isRectangleHorizontallyOverlapped(const QRectF& r1, const QRectF& r2)
{
return isIntervalOverlap(r1.left(), r1.right(), r2.left(), r2.right());
}
inline QColor invertColor(QColor color)
{
qreal r = 0.0;
qreal g = 0.0;
qreal b = 0.0;
qreal a = 0.0;
color.getRgbF(&r, &g, &b, &a);
r = 1.0 - r;
g = 1.0 - g;
b = 1.0 - b;
return QColor::fromRgbF(r, g, b, a);
}
/// Performs linear interpolation of interval [x1, x2] to interval [y1, y2],
/// using formula y = y1 + (x - x1) * (y2 - y1) / (x2 - x1), transformed
/// to formula y = k * x + q, where q = y1 - x1 * k and
/// k = (y2 - y1) / (x2 - x1).
template<typename T>
class PDFLinearInterpolation
{
public:
constexpr inline PDFLinearInterpolation(T x1, T x2, T y1, T y2) :
m_k((y2 - y1) / (x2 - x1)),
m_q(y1 - x1 * m_k)
{
}
/// Maps value from x interval to y interval
constexpr inline T operator()(T x) const
{
return m_k * x + m_q;
}
private:
T m_k;
T m_q;
};
/// Fuzzy compares two points, with given tolerance (so, if points are at lower distance
/// from each other than squared tolerance, they are considered as same and function returns true).
/// \param p1 First point
/// \param p2 Second point
/// \param squaredTolerance Squared tolerance
static inline bool isFuzzyComparedPointsSame(const QPointF& p1, const QPointF& p2, PDFReal squaredTolerance)
{
QPointF dp = p2 - p1;
const qreal squaredDistance = QPointF::dotProduct(dp, dp);
return squaredDistance < squaredTolerance;
}
/// Storage for result of some operation. Stores, if operation was successful, or not and
/// also error message, why operation has failed. Can be converted explicitly to bool.
class PDFOperationResult
{
public:
inline PDFOperationResult(bool success) :
m_success(success)
{
}
inline PDFOperationResult(QString message) :
m_success(false),
m_errorMessage(qMove(message))
{
}
explicit operator bool() const { return m_success; }
const QString& getErrorMessage() const { return m_errorMessage; }
private:
bool m_success;
QString m_errorMessage;
};
} // namespace pdf
#endif // PDFUTILS_H