// ==========================================================
// BMP Loader and Writer
//
// Design and implementation by
// - Floris van den Berg (flvdberg@wxs.nl)
// - Markus Loibl (markus.loibl@epost.de)
// - Martin Weber (martweb@gmx.net)
// - Herv Drolon (drolon@infonie.fr)
// - Michal Novotny (michal@etc.cz)
//
// 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!
// ==========================================================

#include "FreeImage.h"
#include "Utilities.h"

// ----------------------------------------------------------
//   Constants + headers
// ----------------------------------------------------------

static const BYTE RLE_COMMAND     = 0;
static const BYTE RLE_ENDOFLINE   = 0;
static const BYTE RLE_ENDOFBITMAP = 1;
static const BYTE RLE_DELTA       = 2;

#ifndef __MINGW32__		// prevents a bug in mingw32

static const BYTE BI_RGB          = 0;
static const BYTE BI_RLE8         = 1;
static const BYTE BI_RLE4         = 2;
static const BYTE BI_BITFIELDS    = 3;

#endif // __MINGW32__

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

#ifdef _WIN32
#pragma pack(push, 1)
#else
#pragma pack(1)
#endif

#ifndef __MINGW32__
typedef struct tagBITMAPCOREHEADER {
  DWORD   bcSize;
  WORD    bcWidth;
  WORD    bcHeight;
  WORD    bcPlanes;
  WORD    bcBitCnt;
} BITMAPCOREHEADER, *PBITMAPCOREHEADER; 
#endif //__MINGW32__

typedef struct tagBITMAPINFOOS2_1X_HEADER {
  DWORD  biSize;
  WORD   biWidth;
  WORD   biHeight; 
  WORD   biPlanes; 
  WORD   biBitCount;
} BITMAPINFOOS2_1X_HEADER, *PBITMAPINFOOS2_1X_HEADER; 

#ifndef __MINGW32__
typedef struct tagBITMAPFILEHEADER {
  WORD    bfType; 
  DWORD   bfSize;
  WORD    bfReserved1; 
  WORD    bfReserved2;
  DWORD   bfOffBits; 
} BITMAPFILEHEADER, *PBITMAPFILEHEADER;
#endif //__MINGW32__

#ifdef _WIN32
#pragma pack(pop)
#else
#pragma pack()
#endif

// ==========================================================
// Plugin Interface
// ==========================================================

static int s_format_id;

// ==========================================================
// Internal functions
// ==========================================================

#ifdef FREEIMAGE_BIGENDIAN
static void
SwapInfoHeader(BITMAPINFOHEADER *header) {
	SwapLong(&header->biSize);
	SwapLong((DWORD *)&header->biWidth);
	SwapLong((DWORD *)&header->biHeight);
	SwapShort(&header->biPlanes);
	SwapShort(&header->biBitCount);
	SwapLong(&header->biCompression);
	SwapLong(&header->biSizeImage);
	SwapLong((DWORD *)&header->biXPelsPerMeter);
	SwapLong((DWORD *)&header->biYPelsPerMeter);
	SwapLong(&header->biClrUsed);
	SwapLong(&header->biClrImportant);
}

static void
SwapCoreHeader(BITMAPCOREHEADER *header) {
	SwapLong(&header->bcSize);
	SwapShort(&header->bcWidth);
	SwapShort(&header->bcHeight);
	SwapShort(&header->bcPlanes);
	SwapShort(&header->bcBitCnt);
}

static void
SwapOS21XHeader(BITMAPINFOOS2_1X_HEADER *header) {
	SwapLong(&header->biSize);
	SwapShort(&header->biWidth);
	SwapShort(&header->biHeight);
	SwapShort(&header->biPlanes);
	SwapShort(&header->biBitCount);
}

static void
SwapFileHeader(BITMAPFILEHEADER *header) {
	SwapShort(&header->bfType);
  	SwapLong(&header->bfSize);
  	SwapShort(&header->bfReserved1);
  	SwapShort(&header->bfReserved2);
	SwapLong(&header->bfOffBits);
}
#endif

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

/**
Load uncompressed image pixels for 1-, 4-, 8-, 16-, 24- and 32-bit dib
@param io FreeImage IO
@param handle FreeImage IO handle
@param dib Image to be loaded 
@param height Image height
@param pitch Image pitch
@param bit_count Image bit-depth (1-, 4-, 8-, 16-, 24- or 32-bit)
*/
static void 
LoadPixelData(FreeImageIO *io, fi_handle handle, FIBITMAP *dib, int height, int pitch, int bit_count) {
	// Load pixel data
	// NB: height can be < 0 for BMP data
	if (height > 0) {
		io->read_proc((void *)FreeImage_GetBits(dib), height * pitch, 1, handle);
	} else {
		int positiveHeight = abs(height);
		for (int c = 0; c < positiveHeight; ++c) {
			io->read_proc((void *)FreeImage_GetScanLine(dib, positiveHeight - c - 1), pitch, 1, handle);
		}
	}

	// swap as needed
#ifdef FREEIMAGE_BIGENDIAN
	if (bit_count == 16) {
		for(unsigned y = 0; y < FreeImage_GetHeight(dib); y++) {
			WORD *pixel = (WORD *)FreeImage_GetScanLine(dib, y);
			for(unsigned x = 0; x < FreeImage_GetWidth(dib); x++) {
				SwapShort(pixel);
				pixel++;
			}
		}
	}
#endif
#if FREEIMAGE_COLORORDER == FREEIMAGE_COLORORDER_RGB
	if (bit_count == 24 || bit_count == 32) {
		for(unsigned y = 0; y < FreeImage_GetHeight(dib); y++) {
			BYTE *pixel = FreeImage_GetScanLine(dib, y);
			for(unsigned x = 0; x < FreeImage_GetWidth(dib); x++) {
				INPLACESWAP(pixel[0], pixel[2]);
				pixel += (bit_count >> 3);
			}
		}
	}
#endif
}

/**
Load image pixels for 4-bit RLE compressed dib
@param io FreeImage IO
@param handle FreeImage IO handle
@param width Image width
@param height Image height
@param dib Image to be loaded 
@return Returns TRUE if successful, returns FALSE otherwise
*/
static BOOL 
LoadPixelDataRLE4(FreeImageIO *io, fi_handle handle, int width, int height, FIBITMAP *dib) {
	int status_byte = 0;
	BYTE second_byte = 0;
	int bits = 0;

	BYTE *pixels = NULL;	// temporary 8-bit buffer

	try {
		height = abs(height);

		pixels = (BYTE*)malloc(width * height * sizeof(BYTE));
		if(!pixels) throw(1);
		memset(pixels, 0, width * height * sizeof(BYTE));

		BYTE *q = pixels;
		BYTE *end = pixels + height * width;

		for (int scanline = 0; scanline < height; ) {
			if (q < pixels || q  >= end) {
				break;
			}
			if(io->read_proc(&status_byte, sizeof(BYTE), 1, handle) != 1) {
				throw(1);
			}
			if (status_byte != 0)	{
				status_byte = MIN(status_byte, end - q);
				// Encoded mode
				if(io->read_proc(&second_byte, sizeof(BYTE), 1, handle) != 1) {
					throw(1);
				}
				for (int i = 0; i < status_byte; i++)	{
					*q++=(BYTE)((i & 0x01) ? (second_byte & 0x0f) : ((second_byte >> 4) & 0x0f));
				}
				bits += status_byte;
			}
			else {
				// Escape mode
				if(io->read_proc(&status_byte, sizeof(BYTE), 1, handle) != 1) {
					throw(1);
				}
				switch (status_byte) {
					case RLE_ENDOFLINE:
					{
						// End of line
						bits = 0;
						scanline++;
						q = pixels + scanline*width;
					}
					break;

					case RLE_ENDOFBITMAP:
						// End of bitmap
						q = end;
						break;

					case RLE_DELTA:
					{
						// read the delta values

						BYTE delta_x = 0;
						BYTE delta_y = 0;

						if(io->read_proc(&delta_x, sizeof(BYTE), 1, handle) != 1) {
							throw(1);
						}
						if(io->read_proc(&delta_y, sizeof(BYTE), 1, handle) != 1) {
							throw(1);
						}

						// apply them

						bits += delta_x;
						scanline += delta_y;
						q = pixels + scanline*width+bits;
					}
					break;

					default:
					{
						// Absolute mode
						status_byte = MIN(status_byte, end - q);
						for (int i = 0; i < status_byte; i++) {
							if ((i & 0x01) == 0) {
								if(io->read_proc(&second_byte, sizeof(BYTE), 1, handle) != 1) {
									throw(1);
								}
							}
							*q++=(BYTE)((i & 0x01) ? (second_byte & 0x0f) : ((second_byte >> 4) & 0x0f));
						}
						bits += status_byte;
						// Read pad byte
						if (((status_byte & 0x03) == 1) || ((status_byte & 0x03) == 2)) {
							BYTE padding = 0;
							if(io->read_proc(&padding, sizeof(BYTE), 1, handle) != 1) {
								throw(1);
							}
						}
					}
					break;
				}
			}
		}
		
		{
			// Convert to 4-bit
			for(int y = 0; y < height; y++) {
				const BYTE *src = (BYTE*)pixels + y * width;
				BYTE *dst = FreeImage_GetScanLine(dib, y);

				BOOL hinibble = TRUE;

				for (int cols = 0; cols < width; cols++){
					if (hinibble) {
						dst[cols >> 1] = (src[cols] << 4);
					} else {
						dst[cols >> 1] |= src[cols];
					}

					hinibble = !hinibble;
				}
			}
		}

		free(pixels);

		return TRUE;

	} catch(int) {
		if(pixels) free(pixels);
		return FALSE;
	}
}

/**
Load image pixels for 8-bit RLE compressed dib
@param io FreeImage IO
@param handle FreeImage IO handle
@param width Image width
@param height Image height
@param dib Image to be loaded 
@return Returns TRUE if successful, returns FALSE otherwise
*/
static BOOL 
LoadPixelDataRLE8(FreeImageIO *io, fi_handle handle, int width, int height, FIBITMAP *dib) {
	BYTE status_byte = 0;
	BYTE second_byte = 0;
	int scanline = 0;
	int bits = 0;

	for (;;) {
		if( io->read_proc(&status_byte, sizeof(BYTE), 1, handle) != 1) {
			return FALSE;
		}

		switch (status_byte) {
			case RLE_COMMAND :
				if(io->read_proc(&status_byte, sizeof(BYTE), 1, handle) != 1) {
					return FALSE;
				}

				switch (status_byte) {
					case RLE_ENDOFLINE :
						bits = 0;
						scanline++;
						break;

					case RLE_ENDOFBITMAP :
						return TRUE;

					case RLE_DELTA :
					{
						// read the delta values

						BYTE delta_x = 0;
						BYTE delta_y = 0;

						if(io->read_proc(&delta_x, sizeof(BYTE), 1, handle) != 1) {
							return FALSE;
						}
						if(io->read_proc(&delta_y, sizeof(BYTE), 1, handle) != 1) {
							return FALSE;
						}

						// apply them

						bits     += delta_x;
						scanline += delta_y;

						break;
					}

					default :
					{
						if(scanline >= abs(height)) {
							return TRUE;
						}

						int count = MIN((int)status_byte, width - bits);

						BYTE *sline = FreeImage_GetScanLine(dib, scanline);

						if(io->read_proc((void *)(sline + bits), sizeof(BYTE) * count, 1, handle) != 1) {
							return FALSE;
						}
						
						// align run length to even number of bytes 

						if ((status_byte & 1) == 1) {
							if(io->read_proc(&second_byte, sizeof(BYTE), 1, handle) != 1) {
								return FALSE;
							}
						}

						bits += status_byte;													

						break;	
					}
				}

				break;

			default :
			{
				if(scanline >= abs(height)) {
					return TRUE;
				}

				int count = MIN((int)status_byte, width - bits);

				BYTE *sline = FreeImage_GetScanLine(dib, scanline);

				if(io->read_proc(&second_byte, sizeof(BYTE), 1, handle) != 1) {
					return FALSE;
				}

				for (int i = 0; i < count; i++) {
					*(sline + bits) = second_byte;

					bits++;					
				}

				break;
			}
		}
	}
}

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

static FIBITMAP *
LoadWindowsBMP(FreeImageIO *io, fi_handle handle, int flags, unsigned bitmap_bits_offset) {
	FIBITMAP *dib = NULL;

	try {
		// load the info header

		BITMAPINFOHEADER bih;

		io->read_proc(&bih, sizeof(BITMAPINFOHEADER), 1, handle);
#ifdef FREEIMAGE_BIGENDIAN
		SwapInfoHeader(&bih);
#endif

		// keep some general information about the bitmap

		int used_colors = bih.biClrUsed;
		int width       = bih.biWidth;
		int height      = bih.biHeight;		// WARNING: height can be < 0 => check each call using 'height' as a parameter
		int bit_count   = bih.biBitCount;
		int compression = bih.biCompression;
		int pitch       = CalculatePitch(CalculateLine(width, bit_count));

		switch (bit_count) {
			case 1 :
			case 4 :
			case 8 :
			{
				if ((used_colors <= 0) || (used_colors > CalculateUsedPaletteEntries(bit_count)))
					used_colors = CalculateUsedPaletteEntries(bit_count);
				
				// allocate enough memory to hold the bitmap (header, palette, pixels) and read the palette

				dib = FreeImage_Allocate(width, height, bit_count);

				if (dib == NULL)
					throw "DIB allocation failed";

				// set resolution information
				FreeImage_SetDotsPerMeterX(dib, bih.biXPelsPerMeter);
				FreeImage_SetDotsPerMeterY(dib, bih.biYPelsPerMeter);
				
				// load the palette

				io->read_proc(FreeImage_GetPalette(dib), used_colors * sizeof(RGBQUAD), 1, handle);
#if FREEIMAGE_COLORORDER == FREEIMAGE_COLORORDER_RGB
				RGBQUAD *pal = FreeImage_GetPalette(dib);
				for(int i = 0; i < used_colors; i++) {
					INPLACESWAP(pal[i].rgbRed, pal[i].rgbBlue);
				}
#endif

				// seek to the actual pixel data.
				// this is needed because sometimes the palette is larger than the entries it contains predicts

				if (bitmap_bits_offset > (sizeof(BITMAPFILEHEADER) + sizeof(BITMAPINFOHEADER) + (used_colors * sizeof(RGBQUAD))))
					io->seek_proc(handle, bitmap_bits_offset, SEEK_SET);
				
				// read the pixel data

				switch (compression) {
					case BI_RGB :
						LoadPixelData(io, handle, dib, height, pitch, bit_count);				
						return dib;

					case BI_RLE4 :
						if( LoadPixelDataRLE4(io, handle, width, height, dib) ) {
							return dib;
						} else {
							throw "Error encountered while decoding RLE4 BMP data";
						}
						break;

					case BI_RLE8 :
						if( LoadPixelDataRLE8(io, handle, width, height, dib) ) {
							return dib;
						} else {
							throw "Error encountered while decoding RLE8 BMP data";
						}
						break;

					default :
						throw "compression type not supported";
				}
			}
			break; // 1-, 4-, 8-bit

			case 16 :
			{
				if (bih.biCompression == BI_BITFIELDS) {
					DWORD bitfields[3];

					io->read_proc(bitfields, 3 * sizeof(DWORD), 1, handle);

					dib = FreeImage_Allocate(width, height, bit_count, bitfields[0], bitfields[1], bitfields[2]);
				} else {
					dib = FreeImage_Allocate(width, height, bit_count, FI16_555_RED_MASK, FI16_555_GREEN_MASK, FI16_555_BLUE_MASK);
				}

				if (dib == NULL)
					throw "DIB allocation failed";						

				// set resolution information
				FreeImage_SetDotsPerMeterX(dib, bih.biXPelsPerMeter);
				FreeImage_SetDotsPerMeterY(dib, bih.biYPelsPerMeter);

				// load pixel data and swap as needed if OS is Big Endian
				LoadPixelData(io, handle, dib, height, pitch, bit_count);

				return dib;
			}
			break; // 16-bit

			case 24 :
			case 32 :
			{
				if (bih.biCompression == BI_BITFIELDS) {
					DWORD bitfields[3];

					io->read_proc(bitfields, 3 * sizeof(DWORD), 1, handle);

					dib = FreeImage_Allocate(width, height, bit_count, bitfields[0], bitfields[1], bitfields[2]);
				} else {
					if( bit_count == 32 ) {
						dib = FreeImage_Allocate(width, height, bit_count, FI_RGBA_RED_MASK, FI_RGBA_GREEN_MASK, FI_RGBA_BLUE_MASK);
					} else {
						dib = FreeImage_Allocate(width, height, bit_count, FI_RGBA_RED_MASK, FI_RGBA_GREEN_MASK, FI_RGBA_BLUE_MASK);
					}
				}

				if (dib == NULL)
					throw "DIB allocation failed";

				// set resolution information
				FreeImage_SetDotsPerMeterX(dib, bih.biXPelsPerMeter);
				FreeImage_SetDotsPerMeterY(dib, bih.biYPelsPerMeter);

				// Skip over the optional palette 
				// A 24 or 32 bit DIB may contain a palette for faster color reduction

				if (FreeImage_GetColorsUsed(dib) > 0) {
				    io->seek_proc(handle, FreeImage_GetColorsUsed(dib) * sizeof(RGBQUAD), SEEK_CUR);
				} else if ((bih.biCompression != BI_BITFIELDS) && (bitmap_bits_offset > sizeof(BITMAPFILEHEADER) + sizeof(BITMAPINFOHEADER))) {
					io->seek_proc(handle, bitmap_bits_offset, SEEK_SET);
				}

				// read in the bitmap bits
				// load pixel data and swap as needed if OS is Big Endian
				LoadPixelData(io, handle, dib, height, pitch, bit_count);

				// check if the bitmap contains transparency, if so enable it in the header

				FreeImage_SetTransparent(dib, (FreeImage_GetColorType(dib) == FIC_RGBALPHA));

				return dib;
			}
			break; // 24-, 32-bit
		}
	} catch(const char *message) {
		if(dib) {
			FreeImage_Unload(dib);
		}
		if(message) {
			FreeImage_OutputMessageProc(s_format_id, message);
		}
	}

	return NULL;
}

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

static FIBITMAP *
LoadOS22XBMP(FreeImageIO *io, fi_handle handle, int flags, unsigned bitmap_bits_offset) {
	FIBITMAP *dib = NULL;

	try {
		// load the info header

		BITMAPINFOHEADER bih;

		io->read_proc(&bih, sizeof(BITMAPINFOHEADER), 1, handle);
#ifdef FREEIMAGE_BIGENDIAN
		SwapInfoHeader(&bih);
#endif

		// keep some general information about the bitmap

		int used_colors = bih.biClrUsed;
		int width       = bih.biWidth;
		int height      = bih.biHeight;		// WARNING: height can be < 0 => check each read_proc using 'height' as a parameter
		int bit_count   = bih.biBitCount;
		int compression = bih.biCompression;
		int pitch       = CalculatePitch(CalculateLine(width, bit_count));
		
		switch (bit_count) {
			case 1 :
			case 4 :
			case 8 :
			{
				if ((used_colors <= 0) || (used_colors > CalculateUsedPaletteEntries(bit_count)))
					used_colors = CalculateUsedPaletteEntries(bit_count);
					
				// allocate enough memory to hold the bitmap (header, palette, pixels) and read the palette

				dib = FreeImage_Allocate(width, height, bit_count);

				if (dib == NULL)
					throw "DIB allocation failed";

				// set resolution information
				FreeImage_SetDotsPerMeterX(dib, bih.biXPelsPerMeter);
				FreeImage_SetDotsPerMeterY(dib, bih.biYPelsPerMeter);
				
				// load the palette

				io->seek_proc(handle, sizeof(BITMAPFILEHEADER) + bih.biSize, SEEK_SET);

				RGBQUAD *pal = FreeImage_GetPalette(dib);

				for (int count = 0; count < used_colors; count++) {
					FILE_BGR bgr;

					io->read_proc(&bgr, sizeof(FILE_BGR), 1, handle);
					
					pal[count].rgbRed	= bgr.r;
					pal[count].rgbGreen = bgr.g;
					pal[count].rgbBlue	= bgr.b;
				}

				// seek to the actual pixel data.
				// this is needed because sometimes the palette is larger than the entries it contains predicts

				if (bitmap_bits_offset > (sizeof(BITMAPFILEHEADER) + sizeof(BITMAPINFOHEADER) + (used_colors * 3)))
					io->seek_proc(handle, bitmap_bits_offset, SEEK_SET);

				// read the pixel data

				switch (compression) {
					case BI_RGB :
						// load pixel data 
						LoadPixelData(io, handle, dib, height, pitch, bit_count);						
						return dib;

					case BI_RLE4 :
						if( LoadPixelDataRLE4(io, handle, width, height, dib) ) {
							return dib;
						} else {
							throw "Error encountered while decoding RLE4 BMP data";
						}
						break;

					case BI_RLE8 :
						if( LoadPixelDataRLE8(io, handle, width, height, dib) ) {
							return dib;
						} else {
							throw "Error encountered while decoding RLE8 BMP data";
						}
						break;

					default :		
						throw "compression type not supported";
				}	
			}

			case 16 :
			{
				if (bih.biCompression == 3) {
					DWORD bitfields[3];

					io->read_proc(bitfields, 3 * sizeof(DWORD), 1, handle);

					dib = FreeImage_Allocate(width, height, bit_count, bitfields[0], bitfields[1], bitfields[2]);
				} else {
					dib = FreeImage_Allocate(width, height, bit_count, FI16_555_RED_MASK, FI16_555_GREEN_MASK, FI16_555_BLUE_MASK);
				}

				if (dib == NULL)
					throw "DIB allocation failed";						

				// set resolution information
				FreeImage_SetDotsPerMeterX(dib, bih.biXPelsPerMeter);
				FreeImage_SetDotsPerMeterY(dib, bih.biYPelsPerMeter);

				if (bitmap_bits_offset > (sizeof(BITMAPFILEHEADER) + sizeof(BITMAPINFOHEADER) + (used_colors * 3))) {
					io->seek_proc(handle, bitmap_bits_offset, SEEK_SET);
				}

				// load pixel data and swap as needed if OS is Big Endian
				LoadPixelData(io, handle, dib, height, pitch, bit_count);

				return dib;
			}

			case 24 :
			case 32 :
			{
				if( bit_count == 32 ) {
					dib = FreeImage_Allocate(width, height, bit_count, FI_RGBA_RED_MASK, FI_RGBA_GREEN_MASK, FI_RGBA_BLUE_MASK);
				} else {
					dib = FreeImage_Allocate(width, height, bit_count, FI_RGBA_RED_MASK, FI_RGBA_GREEN_MASK, FI_RGBA_BLUE_MASK);
				}

				if (dib == NULL)
					throw "DIB allocation failed";
				
				// set resolution information
				FreeImage_SetDotsPerMeterX(dib, bih.biXPelsPerMeter);
				FreeImage_SetDotsPerMeterY(dib, bih.biYPelsPerMeter);

				// Skip over the optional palette 
				// A 24 or 32 bit DIB may contain a palette for faster color reduction

				if (bitmap_bits_offset > (sizeof(BITMAPFILEHEADER) + sizeof(BITMAPINFOHEADER) + (used_colors * 3)))
					io->seek_proc(handle, bitmap_bits_offset, SEEK_SET);
				
				// read in the bitmap bits
				// load pixel data and swap as needed if OS is Big Endian
				LoadPixelData(io, handle, dib, height, pitch, bit_count);

				// check if the bitmap contains transparency, if so enable it in the header

				FreeImage_SetTransparent(dib, (FreeImage_GetColorType(dib) == FIC_RGBALPHA));

				return dib;
			}
		}
	} catch(const char *message) {
		if(dib)
			FreeImage_Unload(dib);

		FreeImage_OutputMessageProc(s_format_id, message);
	}

	return NULL;
}

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

static FIBITMAP *
LoadOS21XBMP(FreeImageIO *io, fi_handle handle, int flags, unsigned bitmap_bits_offset) {
	FIBITMAP *dib = NULL;

	try {
		BITMAPINFOOS2_1X_HEADER bios2_1x;

		io->read_proc(&bios2_1x, sizeof(BITMAPINFOOS2_1X_HEADER), 1, handle);
#ifdef FREEIMAGE_BIGENDIAN
		SwapOS21XHeader(&bios2_1x);
#endif
		// keep some general information about the bitmap

		int used_colors = 0;
		int width       = bios2_1x.biWidth;
		int height      = bios2_1x.biHeight;	// WARNING: height can be < 0 => check each read_proc using 'height' as a parameter
		int bit_count   = bios2_1x.biBitCount;
		int pitch       = CalculatePitch(CalculateLine(width, bit_count));
		
		switch (bit_count) {
			case 1 :
			case 4 :
			case 8 :
			{
				used_colors = CalculateUsedPaletteEntries(bit_count);
				
				// allocate enough memory to hold the bitmap (header, palette, pixels) and read the palette

				dib = FreeImage_Allocate(width, height, bit_count);

				if (dib == NULL)
					throw "DIB allocation failed";						

				// set resolution information to default values (72 dpi in english units)
				FreeImage_SetDotsPerMeterX(dib, 2835);
				FreeImage_SetDotsPerMeterY(dib, 2835);
				
				// load the palette

				RGBQUAD *pal = FreeImage_GetPalette(dib);

				for (int count = 0; count < used_colors; count++) {
					FILE_BGR bgr;

					io->read_proc(&bgr, sizeof(FILE_BGR), 1, handle);
					
					pal[count].rgbRed	= bgr.r;
					pal[count].rgbGreen = bgr.g;
					pal[count].rgbBlue	= bgr.b;
				}

				// Skip over the optional palette 
				// A 24 or 32 bit DIB may contain a palette for faster color reduction

				io->seek_proc(handle, bitmap_bits_offset, SEEK_SET);
				
				// read the pixel data

				// load pixel data 
				LoadPixelData(io, handle, dib, height, pitch, bit_count);
						
				return dib;
			}

			case 16 :
			{
				dib = FreeImage_Allocate(width, height, bit_count, FI16_555_RED_MASK, FI16_555_GREEN_MASK, FI16_555_BLUE_MASK);

				if (dib == NULL)
					throw "DIB allocation failed";						

				// set resolution information to default values (72 dpi in english units)
				FreeImage_SetDotsPerMeterX(dib, 2835);
				FreeImage_SetDotsPerMeterY(dib, 2835);

				// load pixel data and swap as needed if OS is Big Endian
				LoadPixelData(io, handle, dib, height, pitch, bit_count);

				return dib;
			}

			case 24 :
			case 32 :
			{
				if( bit_count == 32 ) {
					dib = FreeImage_Allocate(width, height, bit_count, FI_RGBA_RED_MASK, FI_RGBA_GREEN_MASK, FI_RGBA_BLUE_MASK);
				} else {
					dib = FreeImage_Allocate(width, height, bit_count, FI_RGBA_RED_MASK, FI_RGBA_GREEN_MASK, FI_RGBA_BLUE_MASK);
				}

				if (dib == NULL)
					throw "DIB allocation failed";						

				// set resolution information to default values (72 dpi in english units)
				FreeImage_SetDotsPerMeterX(dib, 2835);
				FreeImage_SetDotsPerMeterY(dib, 2835);

				// Skip over the optional palette 
				// A 24 or 32 bit DIB may contain a palette for faster color reduction

				// load pixel data and swap as needed if OS is Big Endian
				LoadPixelData(io, handle, dib, height, pitch, bit_count);

				// check if the bitmap contains transparency, if so enable it in the header

				FreeImage_SetTransparent(dib, (FreeImage_GetColorType(dib) == FIC_RGBALPHA));

				return dib;
			}
		}
	} catch(const char *message) {	
		if(dib)
			FreeImage_Unload(dib);

		FreeImage_OutputMessageProc(s_format_id, message);
	}

	return NULL;
}

// ==========================================================
// Plugin Implementation
// ==========================================================

static const char * DLL_CALLCONV
Format() {
	return "BMP";
}

static const char * DLL_CALLCONV
Description() {
	return "Windows or OS/2 Bitmap";
}

static const char * DLL_CALLCONV
Extension() {
	return "bmp";
}

static const char * DLL_CALLCONV
RegExpr() {
	return "^BM";
}

static const char * DLL_CALLCONV
MimeType() {
	return "image/bmp";
}

static BOOL DLL_CALLCONV
Validate(FreeImageIO *io, fi_handle handle) {
	BYTE bmp_signature1[] = { 0x42, 0x4D };
	BYTE bmp_signature2[] = { 0x42, 0x41 };
	BYTE signature[2] = { 0, 0 };

	io->read_proc(signature, 1, sizeof(bmp_signature1), handle);

	if (memcmp(bmp_signature1, signature, sizeof(bmp_signature1)) == 0)
		return TRUE;

	if (memcmp(bmp_signature2, signature, sizeof(bmp_signature2)) == 0)
		return TRUE;

	return FALSE;
}

static BOOL DLL_CALLCONV
SupportsExportDepth(int depth) {
	return (
			(depth == 1) ||
			(depth == 4) ||
			(depth == 8) ||
			(depth == 16) ||
			(depth == 24) ||
			(depth == 32)
		);
}

static BOOL DLL_CALLCONV 
SupportsExportType(FREE_IMAGE_TYPE type) {
	return (type == FIT_BITMAP) ? TRUE : FALSE;
}

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

static FIBITMAP * DLL_CALLCONV
Load(FreeImageIO *io, fi_handle handle, int page, int flags, void *data) {
	if (handle != NULL) {
		BITMAPFILEHEADER bitmapfileheader;
		DWORD type = 0;
		BYTE magic[2];

		// we use this offset value to make seemingly absolute seeks relative in the file
		
		long offset_in_file = io->tell_proc(handle);

		// read the magic

		io->read_proc(&magic, sizeof(magic), 1, handle);

		// compare the magic with the number we know

		// somebody put a comment here explaining the purpose of this loop
		while (memcmp(&magic, "BA", 2) == 0) {
			io->read_proc(&bitmapfileheader.bfSize, sizeof(DWORD), 1, handle);
			io->read_proc(&bitmapfileheader.bfReserved1, sizeof(WORD), 1, handle);
			io->read_proc(&bitmapfileheader.bfReserved2, sizeof(WORD), 1, handle);
			io->read_proc(&bitmapfileheader.bfOffBits, sizeof(DWORD), 1, handle);
			io->read_proc(&magic, sizeof(magic), 1, handle);
		}

		// read the fileheader

		io->seek_proc(handle, 0 - sizeof(magic), SEEK_CUR);
		io->read_proc(&bitmapfileheader, sizeof(BITMAPFILEHEADER), 1, handle);
#ifdef FREEIMAGE_BIGENDIAN
		SwapFileHeader(&bitmapfileheader);
#endif

		// read the first byte of the infoheader

		io->read_proc(&type, sizeof(DWORD), 1, handle);
		io->seek_proc(handle, 0 - sizeof(DWORD), SEEK_CUR);
#ifdef FREEIMAGE_BIGENDIAN
		SwapLong(&type);
#endif

		// call the appropriate load function for the found bitmap type

		if (type == 40)
			return LoadWindowsBMP(io, handle, flags, offset_in_file + bitmapfileheader.bfOffBits);
		
		if (type == 12)
			return LoadOS21XBMP(io, handle, flags, offset_in_file + bitmapfileheader.bfOffBits);

		if (type <= 64)
			return LoadOS22XBMP(io, handle, flags, offset_in_file + bitmapfileheader.bfOffBits);

		FreeImage_OutputMessageProc(s_format_id, "unknown bmp subtype with id %d", type);
	}

	return NULL;
}

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

/**
Encode a 8-bit source buffer into a 8-bit target buffer using a RLE compression algorithm. 
The size of the target buffer must be equal to the size of the source buffer. 
On return, the function will return the real size of the target buffer, which should be less that or equal to the source buffer size. 
@param target 8-bit Target buffer
@param source 8-bit Source buffer
@param size Source/Target input buffer size
@return Returns the target buffer size
*/
static int
RLEEncodeLine(BYTE *target, BYTE *source, int size) {
	BYTE buffer[256];
	int buffer_size = 0;
	int target_pos = 0;

	for (int i = 0; i < size; ++i) {
		if ((i < size - 1) && (source[i] == source[i + 1])) {
			// find a solid block of same bytes

			int j = i + 1;
			int jmax = 254 + i;

			while ((j < size - 1) && (j < jmax) && (source[j] == source[j + 1]))
				++j;

			// if the block is larger than 3 bytes, use it
			// else put the data into the larger pool

			if (((j - i) + 1) > 3) {
				// don't forget to write what we already have in the buffer

				switch(buffer_size) {
					case 0 :
						break;

					case RLE_DELTA :
						target[target_pos++] = 1;
						target[target_pos++] = buffer[0];
						target[target_pos++] = 1;
						target[target_pos++] = buffer[1];
						break;

					case RLE_ENDOFBITMAP :
						target[target_pos++] = (BYTE)buffer_size;
						target[target_pos++] = buffer[0];
						break;

					default :
						target[target_pos++] = RLE_COMMAND;
						target[target_pos++] = (BYTE)buffer_size;
						memcpy(target + target_pos, buffer, buffer_size);

						// prepare for next run
						
						target_pos += buffer_size;

						if ((buffer_size & 1) == 1)
							target_pos++;

						break;
				}

				// write the continuous data

				target[target_pos++] = (BYTE)((j - i) + 1);
				target[target_pos++] = source[i];

				buffer_size = 0;
			} else {
				for (int k = 0; k < (j - i) + 1; ++k) {
					buffer[buffer_size++] = source[i + k];

					if (buffer_size == 254) {
						// write what we have

						target[target_pos++] = RLE_COMMAND;
						target[target_pos++] = (BYTE)buffer_size;
						memcpy(target + target_pos, buffer, buffer_size);

						// prepare for next run

						target_pos += buffer_size;
						buffer_size = 0;
					}
				}
			}

			i = j;
		} else {
			buffer[buffer_size++] = source[i];
		}

		// write the buffer if it's full

		if (buffer_size == 254) {
			target[target_pos++] = RLE_COMMAND;
			target[target_pos++] = (BYTE)buffer_size;
			memcpy(target + target_pos, buffer, buffer_size);

			// prepare for next run

			target_pos += buffer_size;
			buffer_size = 0;
		}
	}

	// write the last bytes

	switch(buffer_size) {
		case 0 :
			break;

		case RLE_DELTA :
			target[target_pos++] = 1;
			target[target_pos++] = buffer[0];
			target[target_pos++] = 1;
			target[target_pos++] = buffer[1];
			break;

		case RLE_ENDOFBITMAP :
			target[target_pos++] = (BYTE)buffer_size;
			target[target_pos++] = buffer[0];
			break;

		default :
			target[target_pos++] = RLE_COMMAND;
			target[target_pos++] = (BYTE)buffer_size;
			memcpy(target + target_pos, buffer, buffer_size);

			// prepare for next run
			
			target_pos += buffer_size;

			if ((buffer_size & 1) == 1)
				target_pos++;

			break;			
	}

	// write the END_OF_LINE marker

	target[target_pos++] = RLE_COMMAND;
	target[target_pos++] = RLE_ENDOFLINE;

	// return the written size

	return target_pos;
}

static BOOL DLL_CALLCONV
Save(FreeImageIO *io, FIBITMAP *dib, fi_handle handle, int page, int flags, void *data) {
	if ((dib != NULL) && (handle != NULL)) {
		// write the file header

		BITMAPFILEHEADER bitmapfileheader;
		bitmapfileheader.bfType = 0x4D42;
		bitmapfileheader.bfSize = sizeof(BITMAPFILEHEADER) + sizeof(BITMAPINFOHEADER) + FreeImage_GetHeight(dib) * FreeImage_GetPitch(dib);
		bitmapfileheader.bfOffBits = sizeof(BITMAPFILEHEADER) + sizeof(BITMAPINFOHEADER) + FreeImage_GetColorsUsed(dib) * sizeof(RGBQUAD);
		bitmapfileheader.bfReserved1 = 0;
		bitmapfileheader.bfReserved2 = 0;

		// take care of the bit fields data of any

		bool bit_fields = (FreeImage_GetBPP(dib) == 16);

		if (bit_fields) {
			bitmapfileheader.bfSize += 3 * sizeof(DWORD);
			bitmapfileheader.bfOffBits += 3 * sizeof(DWORD);
		}

#ifdef FREEIMAGE_BIGENDIAN
		SwapFileHeader(&bitmapfileheader);
#endif
		if (io->write_proc(&bitmapfileheader, sizeof(BITMAPFILEHEADER), 1, handle) != 1)
			return FALSE;		

		// update the bitmap info header

		BITMAPINFOHEADER bih;
		memcpy(&bih, FreeImage_GetInfoHeader(dib), sizeof(BITMAPINFOHEADER));

		if (bit_fields)
			bih.biCompression = BI_BITFIELDS;
		else if ((bih.biBitCount == 8) && (flags & BMP_SAVE_RLE))
			bih.biCompression = BI_RLE8;
		else
			bih.biCompression = BI_RGB;

		// write the bitmap info header

#ifdef FREEIMAGE_BIGENDIAN
		SwapInfoHeader(&bih);
#endif
		if (io->write_proc(&bih, sizeof(BITMAPINFOHEADER), 1, handle) != 1)
			return FALSE;

		// write the bit fields when we are dealing with a 16 bit BMP

		if (bit_fields) {
			DWORD d;

			d = FreeImage_GetRedMask(dib);

			if (io->write_proc(&d, sizeof(DWORD), 1, handle) != 1)
				return FALSE;

			d = FreeImage_GetGreenMask(dib);

			if (io->write_proc(&d, sizeof(DWORD), 1, handle) != 1)
				return FALSE;

			d = FreeImage_GetBlueMask(dib);

			if (io->write_proc(&d, sizeof(DWORD), 1, handle) != 1)
				return FALSE;
		}

		// write the palette

		if (FreeImage_GetPalette(dib) != NULL) {
			RGBQUAD *pal = FreeImage_GetPalette(dib);
			FILE_BGRA bgra;
			for(unsigned i = 0; i < FreeImage_GetColorsUsed(dib); i++ ) {
				bgra.b = pal[i].rgbBlue;
				bgra.g = pal[i].rgbGreen;
				bgra.r = pal[i].rgbRed;
				bgra.a = pal[i].rgbReserved;
				if (io->write_proc(&bgra, sizeof(FILE_BGRA), 1, handle) != 1)
					return FALSE;
			}
		}

		// write the bitmap data... if RLE compression is enable, use it

		unsigned bpp = FreeImage_GetBPP(dib);
		if ((bpp == 8) && (flags & BMP_SAVE_RLE)) {
			BYTE *buffer = new BYTE[FreeImage_GetPitch(dib) * 2];

			for (DWORD i = 0; i < FreeImage_GetHeight(dib); ++i) {
				int size = RLEEncodeLine(buffer, FreeImage_GetScanLine(dib, i), FreeImage_GetLine(dib));

				if (io->write_proc(buffer, size, 1, handle) != 1) {
					delete [] buffer;
					return FALSE;
				}
			}

			buffer[0] = RLE_COMMAND;
			buffer[1] = RLE_ENDOFBITMAP;

			if (io->write_proc(buffer, 2, 1, handle) != 1) {
				delete [] buffer;
				return FALSE;
			}

			delete [] buffer;
#ifdef FREEIMAGE_BIGENDIAN
		} else if (bpp == 16) {
			WORD pixel;
			for(int y = 0; y < FreeImage_GetHeight(dib); y++) {
				BYTE *line = FreeImage_GetScanLine(dib, y);
				for(int x = 0; x < FreeImage_GetWidth(dib); x++) {
					pixel = ((WORD *)line)[x];
					SwapShort(&pixel);
					if (io->write_proc(&pixel, sizeof(WORD), 1, handle) != 1)
						return FALSE;
				}
			}
#endif
#if FREEIMAGE_COLORORDER == FREEIMAGE_COLORORDER_RGB
		} else if (bpp == 24) {
			FILE_BGR bgr;
			for(int y = 0; y < FreeImage_GetHeight(dib); y++) {
				BYTE *line = FreeImage_GetScanLine(dib, y);
				for(int x = 0; x < FreeImage_GetWidth(dib); x++) {
					RGBTRIPLE *triple = ((RGBTRIPLE *)line)+x;
					bgr.b = triple->rgbtBlue;
					bgr.g = triple->rgbtGreen;
					bgr.r = triple->rgbtRed;
					if (io->write_proc(&bgr, sizeof(FILE_BGR), 1, handle) != 1)
						return FALSE;
				}
			}
		} else if (bpp == 32) {
			FILE_BGRA bgra;
			for(int y = 0; y < FreeImage_GetHeight(dib); y++) {
				BYTE *line = FreeImage_GetScanLine(dib, y);
				for(int x = 0; x < FreeImage_GetWidth(dib); x++) {
					RGBQUAD *quad = ((RGBQUAD *)line)+x;
					bgra.b = quad->rgbBlue;
					bgra.g = quad->rgbGreen;
					bgra.r = quad->rgbRed;
					bgra.a = quad->rgbReserved;
					if (io->write_proc(&bgra, sizeof(FILE_BGRA), 1, handle) != 1)
						return FALSE;
				}
			}
#endif
		} else if (io->write_proc(FreeImage_GetBits(dib), FreeImage_GetHeight(dib) * FreeImage_GetPitch(dib), 1, handle) != 1) {
			return FALSE;
		}

		return TRUE;
	} else {
		return FALSE;
	}
}

// ==========================================================
//   Init
// ==========================================================

void DLL_CALLCONV
InitBMP(Plugin *plugin, int format_id) {
	s_format_id = format_id;

	plugin->format_proc = Format;
	plugin->description_proc = Description;
	plugin->extension_proc = Extension;
	plugin->regexpr_proc = RegExpr;
	plugin->open_proc = NULL;
	plugin->close_proc = NULL;
	plugin->pagecount_proc = NULL;
	plugin->pagecapability_proc = NULL;
	plugin->load_proc = Load;
	plugin->save_proc = Save;
	plugin->validate_proc = Validate;
	plugin->mime_proc = MimeType;
	plugin->supports_export_bpp_proc = SupportsExportDepth;
	plugin->supports_export_type_proc = SupportsExportType;
	plugin->supports_icc_profiles_proc = NULL;	// not implemented yet;
}