// ==========================================================

// Utility functions

//

// Design and implementation by

// - Floris van den Berg (flvdberg@wxs.nl)

// - Hervé Drolon <drolon@infonie.fr>

// - Ryan Rubley (ryan@lostreality.org)

// - Mihail Naydenov (mnaydenov@users.sourceforge.net)

//

// This file is part of FreeImage 3

//

// COVERED CODE IS PROVIDED UNDER THIS LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTY

// OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, WITHOUT LIMITATION, WARRANTIES

// THAT THE COVERED CODE IS FREE OF DEFECTS, MERCHANTABLE, FIT FOR A PARTICULAR PURPOSE

// OR NON-INFRINGING. THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE COVERED

// CODE IS WITH YOU. SHOULD ANY COVERED CODE PROVE DEFECTIVE IN ANY RESPECT, YOU (NOT

// THE INITIAL DEVELOPER OR ANY OTHER CONTRIBUTOR) ASSUME THE COST OF ANY NECESSARY

// SERVICING, REPAIR OR CORRECTION. THIS DISCLAIMER OF WARRANTY CONSTITUTES AN ESSENTIAL

// PART OF THIS LICENSE. NO USE OF ANY COVERED CODE IS AUTHORIZED HEREUNDER EXCEPT UNDER

// THIS DISCLAIMER.

//

// Use at your own risk!

// ==========================================================

#ifndef FREEIMAGE_UTILITIES_H

#define FREEIMAGE_UTILITIES_H

// ==========================================================

//   Standard includes used by the library

// ==========================================================

#include <math.h>

#include <stdlib.h> 

#include <memory.h>

#include <stdio.h>

#include <string.h>

#include <stdarg.h>

#include <ctype.h>

#include <assert.h>

#include <errno.h>

#include <float.h>

#include <limits.h>

#include <string>

#include <list>

#include <map>

#include <set>

#include <vector>

#include <stack>

#include <sstream>

#include <algorithm>

#include <limits>

#include <memory>

// ==========================================================

//   Bitmap palette and pixels alignment

// ==========================================================

#define FIBITMAP_ALIGNMENT  16  // We will use a 16 bytes alignment boundary

// Memory allocation on a specified alignment boundary

// defined in BitmapAccess.cpp

void* FreeImage_Aligned_Malloc(size_t amount, size_t alignment);

void FreeImage_Aligned_Free(void* mem);

#if defined(__cplusplus)

extern "C" {

#endif

/**

Allocate a FIBITMAP with possibly no pixel data 

(i.e. only header data and some or all metadata)

@param header_only If TRUE, allocate a 'header only' FIBITMAP, otherwise allocate a full FIBITMAP

@param type Image type

@param width Image width

@param height Image height

@param bpp Number of bits per pixel

@param red_mask Image red mask 

@param green_mask Image green mask

@param blue_mask Image blue mask

@return Returns the allocated FIBITMAP

@see FreeImage_AllocateT

*/

DLL_API FIBITMAP * DLL_CALLCONV FreeImage_AllocateHeaderT(BOOL header_only, FREE_IMAGE_TYPE type, int width, int height, int bpp FI_DEFAULT(8), unsigned red_mask FI_DEFAULT(0), unsigned green_mask FI_DEFAULT(0), unsigned blue_mask FI_DEFAULT(0));

/**

Allocate a FIBITMAP of type FIT_BITMAP, with possibly no pixel data 

(i.e. only header data and some or all metadata)

@param header_only If TRUE, allocate a 'header only' FIBITMAP, otherwise allocate a full FIBITMAP

@param width Image width

@param height Image height

@param bpp Number of bits per pixel

@param red_mask Image red mask 

@param green_mask Image green mask

@param blue_mask Image blue mask

@return Returns the allocated FIBITMAP

@see FreeImage_Allocate

*/

DLL_API FIBITMAP * DLL_CALLCONV FreeImage_AllocateHeader(BOOL header_only, int width, int height, int bpp, unsigned red_mask FI_DEFAULT(0), unsigned green_mask FI_DEFAULT(0), unsigned blue_mask FI_DEFAULT(0));

/**

Allocate a FIBITMAP with no pixel data and wrap a user provided pixel buffer

@param ext_bits Pointer to external user's pixel buffer

@param ext_pitch Pointer to external user's pixel buffer pitch

@param type Image type

@param width Image width

@param height Image height

@param bpp Number of bits per pixel

@param red_mask Image red mask 

@param green_mask Image green mask

@param blue_mask Image blue mask

@return Returns the allocated FIBITMAP

@see FreeImage_ConvertFromRawBitsEx

*/

DLL_API FIBITMAP * DLL_CALLCONV FreeImage_AllocateHeaderForBits(BYTE *ext_bits, unsigned ext_pitch, FREE_IMAGE_TYPE type, int width, int height, int bpp, unsigned red_mask, unsigned green_mask, unsigned blue_mask);

/**

Helper for 16-bit FIT_BITMAP

@see FreeImage_GetRGBMasks

*/

DLL_API BOOL DLL_CALLCONV FreeImage_HasRGBMasks(FIBITMAP *dib);

#if defined(__cplusplus)

}

#endif

// ==========================================================

//   File I/O structs

// ==========================================================

// these structs are for file I/O and should not be confused with similar

// structs in FreeImage.h which are for in-memory bitmap handling

#ifdef _WIN32

#pragma pack(push, 1)

#else

#pragma pack(1)

#endif // _WIN32

typedef struct tagFILE_RGBA {

  unsigned char r,g,b,a;

} FILE_RGBA;

typedef struct tagFILE_BGRA {

  unsigned char b,g,r,a;

} FILE_BGRA;

typedef struct tagFILE_RGB {

  unsigned char r,g,b;

} FILE_RGB;

typedef struct tagFILE_BGR {

  unsigned char b,g,r;

} FILE_BGR;

#ifdef _WIN32

#pragma pack(pop)

#else

#pragma pack()

#endif // _WIN32

// ==========================================================

//   Template utility functions

// ==========================================================

/// Max function

template <class T> T MAX(const T &a, const T &b) {

  return (a > b) ? a: b;

}

Unexecuted instantiation: int MAX<int>(int const&, int const&)

Unexecuted instantiation: double MAX<double>(double const&, double const&)

Unexecuted instantiation: unsigned int MAX<unsigned int>(unsigned int const&, unsigned int const&)

Unexecuted instantiation: unsigned long MAX<unsigned long>(unsigned long const&, unsigned long const&)

/// Min function

template <class T> T MIN(const T &a, const T &b) {

  return (a < b) ? a: b;

}

int MIN<int>(int const&, int const&)

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template <class T> T MIN(const T &a, const T &b) {

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  return (a < b) ? a: b;

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}

unsigned long MIN<unsigned long>(unsigned long const&, unsigned long const&)

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template <class T> T MIN(const T &a, const T &b) {

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  return (a < b) ? a: b;

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}

Unexecuted instantiation: unsigned int MIN<unsigned int>(unsigned int const&, unsigned int const&)

Unexecuted instantiation: long MIN<long>(long const&, long const&)

Unexecuted instantiation: unsigned short MIN<unsigned short>(unsigned short const&, unsigned short const&)

Unexecuted instantiation: double MIN<double>(double const&, double const&)

/// INPLACESWAP adopted from codeguru.com 

template <class T> void INPLACESWAP(T& a, T& b) {

  a ^= b; b ^= a; a ^= b;

}

/// Clamp function

template <class T> T CLAMP(const T &value, const T &min_value, const T &max_value) {

  return ((value < min_value) ? min_value : (value > max_value) ? max_value : value);

}

Unexecuted instantiation: unsigned int CLAMP<unsigned int>(unsigned int const&, unsigned int const&, unsigned int const&)

Unexecuted instantiation: float CLAMP<float>(float const&, float const&, float const&)

/** This procedure computes minimum min and maximum max

 of n numbers using only (3n/2) - 2 comparisons.

 min = L[i1] and max = L[i2].

 ref: Aho A.V., Hopcroft J.E., Ullman J.D., 

 The design and analysis of computer algorithms, 

 Addison-Wesley, Reading, 1974.

*/

template <class T> void 

MAXMIN(const T* L, long n, T& max, T& min) {

  long i1, i2, i, j;

  T x1, x2;

  long k1, k2;

  i1 = 0; i2 = 0; min = L[0]; max = L[0]; j = 0;

  if((n % 2) != 0)  j = 1;

  for(i = j; i < n; i+= 2) {

    k1 = i; k2 = i+1;

    x1 = L[k1]; x2 = L[k2];

    if(x1 > x2) {

      k1 = k2;  k2 = i;

      x1 = x2;  x2 = L[k2];

    }

    if(x1 < min) {

      min = x1;  i1 = k1;

    }

    if(x2 > max) {

      max = x2;  i2 = k2;

    }

  }

}

// ==========================================================

//   Utility functions

// ==========================================================

#ifndef _WIN32

inline char*

i2a(unsigned i, char *a, unsigned r) {

  if (i/r > 0) a = i2a(i/r,a,r);

  *a = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"[i%r];

  return a+1;

}

/** 

 Transforms integer i into an ascii string and stores the result in a; 

 string is encoded in the base indicated by r.

 @param i Number to be converted

 @param a String result

 @param r Base of value; must be in the range 2 - 36

 @return Returns a

*/

inline char *

_itoa(int i, char *a, int r) {

  r = ((r < 2) || (r > 36)) ? 10 : r;

  if(i < 0) {

    *a = '-';

    *i2a(-i, a+1, r) = 0;

  }

  else *i2a(i, a, r) = 0;

  return a;

}

#endif // !_WIN32

inline unsigned char

HINIBBLE (unsigned char byte) {

  return byte & 0xF0;

}

inline unsigned char

LOWNIBBLE (unsigned char byte) {

  return byte & 0x0F;

}

inline int

CalculateUsedBits(int bits) {

  int bit_count = 0;

  unsigned bit = 1;

  for (unsigned i = 0; i < 32; i++) {

    if ((bits & bit) == bit) {

      bit_count++;

    }

    bit <<= 1;

  }

  return bit_count;

}

inline unsigned

CalculateLine(const unsigned width, const unsigned bitdepth) {

  return (unsigned)( ((unsigned long long)width * bitdepth + 7) / 8 );

}

inline unsigned

CalculatePitch(const unsigned line) {

  return (line + 3) & ~3;

}

inline unsigned

CalculateUsedPaletteEntries(const unsigned bit_count) {

  if ((bit_count >= 1) && (bit_count <= 8)) {

    return 1 << bit_count;

  }

  return 0;

}

inline BYTE*

CalculateScanLine(BYTE *bits, const unsigned pitch, const int scanline) {

  return bits ? (bits + ((size_t)pitch * scanline)) : NULL;

}

// ----------------------------------------------------------

/**

Fast generic assign (faster than for loop)

@param dst Destination pixel

@param src Source pixel

@param bytesperpixel # of bytes per pixel

*/

inline void 

AssignPixel(BYTE* dst, const BYTE* src, unsigned bytesperpixel) {

  switch (bytesperpixel) {

    case 1: // FIT_BITMAP (8-bit)

      *dst = *src;

      break;

    case 2: // FIT_UINT16 / FIT_INT16 / 16-bit

      *(reinterpret_cast<WORD*>(dst)) = *(reinterpret_cast<const WORD*> (src));

      break;

    case 3: // FIT_BITMAP (24-bit)

      *(reinterpret_cast<WORD*>(dst)) = *(reinterpret_cast<const WORD*> (src));

      dst[2] = src[2];

      break;

    case 4: // FIT_BITMAP (32-bit) / FIT_UINT32 / FIT_INT32 / FIT_FLOAT

      *(reinterpret_cast<DWORD*>(dst)) = *(reinterpret_cast<const DWORD*> (src));

      break;

    case 6: // FIT_RGB16 (3 x 16-bit)

      *(reinterpret_cast<DWORD*>(dst)) = *(reinterpret_cast<const DWORD*> (src));

      *(reinterpret_cast<WORD*>(dst + 4)) = *(reinterpret_cast<const WORD*> (src + 4)); 

      break;

    // the rest can be speeded up with int64

    case 8: // FIT_RGBA16 (4 x 16-bit)

      *(reinterpret_cast<DWORD*>(dst)) = *(reinterpret_cast<const DWORD*> (src));

      *(reinterpret_cast<DWORD*>(dst + 4)) = *(reinterpret_cast<const DWORD*> (src + 4)); 

      break;

    case 12: // FIT_RGBF (3 x 32-bit IEEE floating point)

      *(reinterpret_cast<float*>(dst)) = *(reinterpret_cast<const float*> (src));

      *(reinterpret_cast<float*>(dst + 4)) = *(reinterpret_cast<const float*> (src + 4));

      *(reinterpret_cast<float*>(dst + 8)) = *(reinterpret_cast<const float*> (src + 8));

      break;

    case 16: // FIT_RGBAF (4 x 32-bit IEEE floating point)

      *(reinterpret_cast<float*>(dst)) = *(reinterpret_cast<const float*> (src));

      *(reinterpret_cast<float*>(dst + 4)) = *(reinterpret_cast<const float*> (src + 4));

      *(reinterpret_cast<float*>(dst + 8)) = *(reinterpret_cast<const float*> (src + 8));

      *(reinterpret_cast<float*>(dst + 12)) = *(reinterpret_cast<const float*> (src + 12));

      break;

    default:

      assert(FALSE);

  }

}

/**

Swap red and blue channels in a 24- or 32-bit dib. 

@return Returns TRUE if successful, returns FALSE otherwise

@see See definition in Conversion.cpp

*/

BOOL SwapRedBlue32(FIBITMAP* dib);

/**

Inplace convert CMYK to RGBA.(8- and 16-bit). 

Alpha is filled with the first extra channel if any or white otherwise.

@return Returns TRUE if successful, returns FALSE otherwise

@see See definition in Conversion.cpp

*/

BOOL ConvertCMYKtoRGBA(FIBITMAP* dib);

/**

Inplace convert CIELab to RGBA (8- and 16-bit).

@return Returns TRUE if successful, returns FALSE otherwise

@see See definition in Conversion.cpp

*/

BOOL ConvertLABtoRGB(FIBITMAP* dib);

/**

RGBA to RGB conversion

@see See definition in Conversion.cpp

*/

FIBITMAP* RemoveAlphaChannel(FIBITMAP* dib);

/**

Rotate a dib according to Exif info

@param dib Input / Output dib to rotate

@see Exif.cpp, PluginJPEG.cpp

*/

void RotateExif(FIBITMAP **dib);

// ==========================================================

//   Big Endian / Little Endian utility functions

// ==========================================================

inline WORD 

__SwapUInt16(WORD arg) { 

#if defined(_MSC_VER) && _MSC_VER >= 1310 

  return _byteswap_ushort(arg); 

#elif defined(__i386__) && defined(__GNUC__) 

  __asm__("xchgb %b0, %h0" : "+q" (arg)); 

  return arg; 

#elif defined(__ppc__) && defined(__GNUC__) 

  WORD result; 

  __asm__("lhbrx %0,0,%1" : "=r" (result) : "r" (&arg), "m" (arg)); 

  return result; 

#else 

  // swap bytes 

  WORD result;

  result = ((arg << 8) & 0xFF00) | ((arg >> 8) & 0x00FF); 

  return result; 

#endif 

} 

inline DWORD 

__SwapUInt32(DWORD arg) { 

#if defined(_MSC_VER) && _MSC_VER >= 1310 

  return _byteswap_ulong(arg); 

#elif defined(__i386__) && defined(__GNUC__) 

  __asm__("bswap %0" : "+r" (arg)); 

  return arg; 

#elif defined(__ppc__) && defined(__GNUC__) 

  DWORD result; 

  __asm__("lwbrx %0,0,%1" : "=r" (result) : "r" (&arg), "m" (arg)); 

  return result; 

#else 

  // swap words then bytes

  DWORD result; 

  result = ((arg & 0x000000FF) << 24) | ((arg & 0x0000FF00) << 8) | ((arg >> 8) & 0x0000FF00) | ((arg >> 24) & 0x000000FF); 

  return result; 

#endif 

} 

inline void

SwapShort(WORD *sp) {

  *sp = __SwapUInt16(*sp);

}

inline void

SwapLong(DWORD *lp) {

  *lp = __SwapUInt32(*lp);

}

inline void

SwapInt64(UINT64 *arg) {

#if defined(_MSC_VER) && _MSC_VER >= 1310

  *arg = _byteswap_uint64(*arg);

#else

  union Swap {

    UINT64 sv;

    DWORD ul[2];

  } tmp, result;

  tmp.sv = *arg;

  SwapLong(&tmp.ul[0]);

  SwapLong(&tmp.ul[1]);

  result.ul[0] = tmp.ul[1];

  result.ul[1] = tmp.ul[0];

  *arg = result.sv;

#endif

}

// ==========================================================

//   Greyscale and color conversion

// ==========================================================

/**

Extract the luminance channel L from a RGBF image. 

Luminance is calculated from the sRGB model using a D65 white point, using the Rec.709 formula : 

L = ( 0.2126 * r ) + ( 0.7152 * g ) + ( 0.0722 * b )

Reference : 

A Standard Default Color Space for the Internet - sRGB. 

[online] http://www.w3.org/Graphics/Color/sRGB

*/

#define LUMA_REC709(r, g, b)  (0.2126F * r + 0.7152F * g + 0.0722F * b)

#define GREY(r, g, b) (BYTE)(LUMA_REC709(r, g, b) + 0.5F)

/*

#define GREY(r, g, b) (BYTE)(((WORD)r * 77 + (WORD)g * 150 + (WORD)b * 29) >> 8)  // .299R + .587G + .114B

*/

/*

#define GREY(r, g, b) (BYTE)(((WORD)r * 169 + (WORD)g * 256 + (WORD)b * 87) >> 9) // .33R + 0.5G + .17B

*/

/**

Convert a RGB 24-bit value to a 16-bit 565 value

*/

#define RGB565(b, g, r) ((((b) >> 3) << FI16_565_BLUE_SHIFT) | (((g) >> 2) << FI16_565_GREEN_SHIFT) | (((r) >> 3) << FI16_565_RED_SHIFT))

/**

Convert a RGB 24-bit value to a 16-bit 555 value

*/

#define RGB555(b, g, r) ((((b) >> 3) << FI16_555_BLUE_SHIFT) | (((g) >> 3) << FI16_555_GREEN_SHIFT) | (((r) >> 3) << FI16_555_RED_SHIFT))

/**

Returns TRUE if the format of a dib is RGB565

*/

#define IS_FORMAT_RGB565(dib) ((FreeImage_GetRedMask(dib) == FI16_565_RED_MASK) && (FreeImage_GetGreenMask(dib) == FI16_565_GREEN_MASK) && (FreeImage_GetBlueMask(dib) == FI16_565_BLUE_MASK))

/**

Convert a RGB565 or RGB555 RGBQUAD pixel to a WORD

*/

#define RGBQUAD_TO_WORD(dib, color) (IS_FORMAT_RGB565(dib) ? RGB565((color)->rgbBlue, (color)->rgbGreen, (color)->rgbRed) : RGB555((color)->rgbBlue, (color)->rgbGreen, (color)->rgbRed))

/**

Create a greyscale palette

*/

#define CREATE_GREYSCALE_PALETTE(palette, entries) \

  for (unsigned i = 0, v = 0; i < entries; i++, v += 0x00FFFFFF / (entries - 1)) { \

    ((unsigned *)palette)[i] = v; \

  }

/**

Create a reverse greyscale palette

*/

#define CREATE_GREYSCALE_PALETTE_REVERSE(palette, entries) \

  for (unsigned i = 0, v = 0x00FFFFFF; i < entries; i++, v -= (0x00FFFFFF / (entries - 1))) { \

    ((unsigned *)palette)[i] = v; \

  }

// ==========================================================

//   Generic error messages

// ==========================================================

static const char *FI_MSG_ERROR_MEMORY = "Memory allocation failed";

static const char *FI_MSG_ERROR_DIB_MEMORY = "DIB allocation failed, maybe caused by an invalid image size or by a lack of memory";

static const char *FI_MSG_ERROR_PARSING = "Parsing error";

static const char *FI_MSG_ERROR_MAGIC_NUMBER = "Invalid magic number";

static const char *FI_MSG_ERROR_UNSUPPORTED_FORMAT = "Unsupported image format";

static const char *FI_MSG_ERROR_INVALID_FORMAT = "Invalid file format";

static const char *FI_MSG_ERROR_CORRUPTED_IMAGE = "Image is corrupted";

static const char *FI_MSG_ERROR_UNSUPPORTED_COMPRESSION = "Unsupported compression type";

static const char *FI_MSG_WARNING_INVALID_THUMBNAIL = "Warning: attached thumbnail cannot be written to output file (invalid format) - Thumbnail saving aborted";

#endif // FREEIMAGE_UTILITIES_H