path: root/src/Fl_BMP_Image.cxx

//
// "$Id$"
//
// Fl_BMP_Image routines.
//
// Copyright 1997-2010 by Easy Software Products.
// Image support by Matthias Melcher, Copyright 2000-2009.
//
// This library is free software. Distribution and use rights are outlined in
// the file "COPYING" which should have been included with this file.  If this
// file is missing or damaged, see the license at:
//
//     http://www.fltk.org/COPYING.php
//
// Please report all bugs and problems on the following page:
//
//     http://www.fltk.org/str.php
//
// Contents:
//
//   Fl_BMP_Image::Fl_BMP_Image() - Load a BMP image file.
//

//
// Include necessary header files...
//

#include <FL/Fl_BMP_Image.H>
#include <FL/fl_utf8.h>
#include <FL/Fl.H>
#include <stdio.h>
#include <stdlib.h>


//
// BMP definitions...
//

#ifndef BI_RGB
#  define BI_RGB       0             // No compression - straight BGR data
#  define BI_RLE8      1             // 8-bit run-length compression
#  define BI_RLE4      2             // 4-bit run-length compression
#  define BI_BITFIELDS 3             // RGB bitmap with RGB masks
#endif // !BI_RGB


//
// Local reader class...
//

class BMPReader
{
public:
  BMPReader() :
  pIsFile(0), pIsData(0),
  pFile(0L), pData(0L), pStart(0L),
  pName(0L)
  { }
  int open(const char *filename) {
    if (filename)
      pName = strdup(filename);
    if ((pFile = fl_fopen(filename, "rb")) == NULL) {
      return -1;
    } else {
      pIsFile = 1;
      return 0;
    }
  }
  int open(const char *imagename, const unsigned char *data) {
    if (imagename)
      pName = strdup(imagename);
    if (data) {
      pStart = pData = data;
      pIsData = 1;
      return 0;
    } else {
      return -1;
    }
  }
  ~BMPReader() {
    if (pIsFile && pFile) {
      fclose(pFile);
    }
    if (pName)
      ::free(pName);
  }
  uchar read_byte() {
    if (pIsFile) {
      return getc(pFile);
    } else if (pIsData) {
      return *pData++;
    } else {
      return 0;
    }
  }
  // 'read_word()' - Read a 16-bit unsigned integer.
  unsigned short read_word() {
    unsigned char b0, b1;  // Bytes from file
    if (pIsFile) {
      b0 = (uchar)getc(pFile);
      b1 = (uchar)getc(pFile);
      return ((b1 << 8) | b0);
    } else if (pIsData) {
      b0 = *pData++;
      b1 = *pData++;
      return ((b1 << 8) | b0);
    } else {
      return 0;
    }
  }
  // 'read_dword()' - Read a 32-bit unsigned integer.
  unsigned int read_dword() {
    unsigned char b0, b1, b2, b3;  // Bytes from file
    if (pIsFile) {
      b0 = (uchar)getc(pFile);
      b1 = (uchar)getc(pFile);
      b2 = (uchar)getc(pFile);
      b3 = (uchar)getc(pFile);
      return ((((((b3 << 8) | b2) << 8) | b1) << 8) | b0);
    } else if (pIsData) {
      b0 = *pData++;
      b1 = *pData++;
      b2 = *pData++;
      b3 = *pData++;
      return ((((((b3 << 8) | b2) << 8) | b1) << 8) | b0);
    } else {
      return 0;
    }
  }
  // 'read_long()' - Read a 32-bit signed integer.
  int read_long() {
    return (int)read_dword();
  };
  void seek(unsigned int n) {
    if (pIsFile) {
      fseek(pFile, n , SEEK_SET);
    } else if (pIsData) {
      pData = pStart + n;
    }
  }
  const char *name() { return pName; }
private:
  char pIsFile;
  char pIsData;
  FILE *pFile;
  const unsigned char *pData;
  const unsigned char *pStart;
  char *pName;
};


/**
 The constructor loads the named BMP image from the given bmp filename.

 The destructor frees all memory and server resources that are used by
 the image.

 Use Fl_Image::fail() to check if Fl_BMP_Image failed to load. fail() returns
 ERR_FILE_ACCESS if the file could not be opened or read, ERR_FORMAT if the
 BMP format could not be decoded, and ERR_NO_IMAGE if the image could not
 be loaded for another reason.
 */
Fl_BMP_Image::Fl_BMP_Image(const char *filename) // I - File to read
: Fl_RGB_Image(0,0,0)
{
  BMPReader f;
  if (f.open(filename)==-1) {
    ld(ERR_FORMAT);
  } else {
    read(f);
  }
}

/**
 The constructor loads the named BMP image from the given memory address.

 \param[in] imagename the name of the bitmap
 \param[in] data a pointer to the BMP data in memory. There is no checking for buffer overruns

 \see Fl_BMP_Image::Fl_BMP_Image(const char *filename)
*/
Fl_BMP_Image::Fl_BMP_Image(const char *imagename, const unsigned char *data)
: Fl_RGB_Image(0,0,0)
{
  BMPReader d;
  if (d.open(imagename, data)==-1) {
    ld(ERR_FORMAT);
  } else {
    read(d);
  }
}


void Fl_BMP_Image::read(class BMPReader &rdr)
{
  int     info_size,    // Size of info header
          depth,        // Depth of image (bits)
          bDepth = 3,   // Depth of image (bytes)
          compression,  // Type of compression
          colors_used,  // Number of colors used
          x, y,         // Looping vars
          color,        // Color of RLE pixel
          repcount,     // Number of times to repeat
          temp,         // Temporary color
          align,        // Alignment bytes
          dataSize,     // number of bytes in image data set
          row_order,    // 1 = normal;  -1 = flipped row order
          start_y,      // Beginning Y
          end_y;        // Ending Y
  long    offbits;      // Offset to image data
  uchar   bit,          // Bit in image
          byte;         // Byte in image
  uchar   *ptr;         // Pointer into pixels
  uchar   colormap[256][3]; // Colormap
  uchar   havemask;     // Single bit mask follows image data
  int     use_5_6_5;    // Use 5:6:5 for R:G:B channels in 16 bit images

  // Reader is already open at this point.

  // Get the header...
  byte = rdr.read_byte();	// Check "BM" sync chars
  bit  = rdr.read_byte();
  if (byte != 'B' || bit != 'M') {
    ld(ERR_FORMAT);
    return;
  }

  rdr.read_dword();		// Skip size
  rdr.read_word();		// Skip reserved stuff
  rdr.read_word();
  offbits = (long)rdr.read_dword();// Read offset to image data

  // Then the bitmap information...
  info_size = rdr.read_dword();

  //  printf("offbits = %ld, info_size = %d\n", offbits, info_size);

  havemask  = 0;
  row_order = -1;
  use_5_6_5 = 0;

  if (info_size < 40) {
    // Old Windows/OS2 BMP header...
    w(rdr.read_word());
    h(rdr.read_word());
    rdr.read_word();
    depth = rdr.read_word();
    compression = BI_RGB;
    colors_used = 0;

    repcount = info_size - 12;
  } else {
    // New BMP header...
    w(rdr.read_long());
    // If the height is negative, the row order is flipped
    temp = rdr.read_long();
    if (temp < 0) row_order = 1;
    h(abs(temp));
    rdr.read_word();
    depth = rdr.read_word();
    compression = rdr.read_dword();
    dataSize = rdr.read_dword();
    rdr.read_long();
    rdr.read_long();
    colors_used = rdr.read_dword();
    rdr.read_dword();

    repcount = info_size - 40;

    if (!compression && depth>=8 && w()>32/depth) {
      int Bpp = depth/8;
      int maskSize = (((w()*Bpp+3)&~3)*h()) + (((((w()+7)/8)+3)&~3)*h());
      if (maskSize==2*dataSize) {
        havemask = 1;
        h(h()/2);
        bDepth = 4;
      }
    }
  }

  //  printf("w() = %d, h() = %d, depth = %d, compression = %d, colors_used = %d, repcount = %d\n",
  //         w(), h(), depth, compression, colors_used, repcount);

  // Skip remaining header bytes...
  while (repcount > 0) {
    rdr.read_byte();
    repcount --;
  }

  // Check header data...
  if (!w() || !h() || !depth) {
    w(0); h(0); d(0); ld(ERR_FORMAT);
    return;
  }

  // Get colormap...
  if (colors_used == 0 && depth <= 8)
    colors_used = 1 << depth;

  for (repcount = 0; repcount < colors_used; repcount ++) {
    // Read BGR color...
    colormap[repcount][0] = rdr.read_byte();
    colormap[repcount][1] = rdr.read_byte();
    colormap[repcount][2] = rdr.read_byte();

    // Skip pad byte for new BMP files...
    if (info_size > 12) rdr.read_byte();
  }

  // Read first dword of colormap. It tells us if 5:5:5 or 5:6:5 for 16 bit
  if (depth == 16)
    use_5_6_5 = (rdr.read_dword() == 0xf800);

  // Set byte depth for RGBA images
  if (depth == 32)
    bDepth=4;

  // Setup image and buffers...
  d(bDepth);
  if (offbits) rdr.seek(offbits);

  if (((size_t)w()) * h() * d() > max_size() ) {
    Fl::warning("BMP file \"%s\" is too large!\n", rdr.name());
    w(0); h(0); d(0); ld(ERR_FORMAT);
    return;
  }
  array = new uchar[w() * h() * d()];
  alloc_array = 1;

  // Read the image data...
  color = 0;
  repcount = 0;
  align = 0;
  byte  = 0;
  temp  = 0;

  if (row_order < 0) {
    start_y = h() - 1;
    end_y   = -1;
  } else {
    start_y = 0;
    end_y   = h();
  }

  for (y = start_y; y != end_y; y += row_order) {
    ptr = (uchar *)array + y * w() * d();

    switch (depth)
    {
      case 1 : // Bitmap
        for (x = w(), bit = 128; x > 0; x --) {
          if (bit == 128) byte = rdr.read_byte();

          if (byte & bit) {
            *ptr++ = colormap[1][2];
            *ptr++ = colormap[1][1];
            *ptr++ = colormap[1][0];
          } else {
            *ptr++ = colormap[0][2];
            *ptr++ = colormap[0][1];
            *ptr++ = colormap[0][0];
          }

          if (bit > 1)
            bit >>= 1;
          else
            bit = 128;
        }

        // Read remaining bytes to align to 32 bits...
        for (temp = (w() + 7) / 8; temp & 3; temp ++) {
          rdr.read_byte();
        }
        break;

      case 4 : // 16-color
        for (x = w(), bit = 0xf0; x > 0; x --) {
          // Get a new repcount as needed...
          if (repcount == 0) {
            if (compression != BI_RLE4) {
              repcount = 2;
              color = -1;
            } else {
              while (align > 0) {
                align --;
                rdr.read_byte();
              }

              if ((repcount = rdr.read_byte()) == 0) {
                if ((repcount = rdr.read_byte()) == 0) {
                  // End of line...
                  x ++;
                  continue;
                } else if (repcount == 1) {
                  // End of image...
                  break;
                } else if (repcount == 2) {
                  // Delta...
                  repcount = rdr.read_byte() * rdr.read_byte() * w();
                  color = 0;
                } else {
                  // Absolute...
                  color = -1;
                  align = ((4 - (repcount & 3)) / 2) & 1;
                }
              } else {
                color = rdr.read_byte();
              }
            }
          }

          // Get a new color as needed...
          repcount --;

          // Extract the next pixel...
          if (bit == 0xf0) {
            // Get the next color byte as needed...
            if (color < 0) temp = rdr.read_byte();
            else temp = color;

            // Copy the color value...
            *ptr++ = colormap[(temp >> 4) & 15][2];
            *ptr++ = colormap[(temp >> 4) & 15][1];
            *ptr++ = colormap[(temp >> 4) & 15][0];

            bit  = 0x0f;
          } else {
            bit  = 0xf0;

            // Copy the color value...
            *ptr++ = colormap[temp & 15][2];
            *ptr++ = colormap[temp & 15][1];
            *ptr++ = colormap[temp & 15][0];
          }

        }

        if (!compression) {
          // Read remaining bytes to align to 32 bits...
          for (temp = (w() + 1) / 2; temp & 3; temp ++) {
            rdr.read_byte();
          }
        }
        break;

      case 8 : // 256-color
        for (x = w(); x > 0; x --) {
          // Get a new repcount as needed...
          if (compression != BI_RLE8) {
            repcount = 1;
            color = -1;
          }

          if (repcount == 0) {
            while (align > 0) {
              align --;
              rdr.read_byte();
            }

            if ((repcount = rdr.read_byte()) == 0) {
              if ((repcount = rdr.read_byte()) == 0) {
                // End of line...
                x ++;
                continue;
              } else if (repcount == 1) {
                // End of image...
                break;
              } else if (repcount == 2) {
                // Delta...
                repcount = rdr.read_byte() * rdr.read_byte() * w();
                color = 0;
              } else {
                // Absolute...
                color = -1;
                align = (2 - (repcount & 1)) & 1;
              }
            } else {
              color = rdr.read_byte();
            }
          }

          // Get a new color as needed...
          if (color < 0) temp = rdr.read_byte();
          else temp = color;

          repcount --;

          // Copy the color value...
          *ptr++ = colormap[temp][2];
          *ptr++ = colormap[temp][1];
          *ptr++ = colormap[temp][0];
          if (havemask) ptr++;
        }

        if (!compression) {
          // Read remaining bytes to align to 32 bits...
          for (temp = w(); temp & 3; temp ++) {
            rdr.read_byte();
          }
        }
        break;

      case 16 : // 16-bit 5:5:5 or 5:6:5 RGB
        for (x = w(); x > 0; x --, ptr += bDepth) {
          uchar b = rdr.read_byte(), a = rdr.read_byte() ;
          if (use_5_6_5) {
            ptr[2] = (uchar)(( b << 3 ) & 0xf8);
            ptr[1] = (uchar)(((a << 5) & 0xe0) | ((b >> 3) & 0x1c));
            ptr[0] = (uchar)(a & 0xf8);
          } else {
            ptr[2] = (uchar)((b << 3) & 0xf8);
            ptr[1] = (uchar)(((a << 6) & 0xc0) | ((b >> 2) & 0x38));
            ptr[0] = (uchar)((a<<1) & 0xf8);
          }
        }

        // Read remaining bytes to align to 32 bits...
        for (temp = w() * 2; temp & 3; temp ++) {
          rdr.read_byte();
        }
        break;

      case 24 : // 24-bit RGB
        for (x = w(); x > 0; x --, ptr += bDepth) {
          ptr[2] = rdr.read_byte();
          ptr[1] = rdr.read_byte();
          ptr[0] = rdr.read_byte();
        }

        // Read remaining bytes to align to 32 bits...
        for (temp = w() * 3; temp & 3; temp ++) {
          rdr.read_byte();
        }
        break;

      case 32 : // 32-bit RGBA
        for (x = w(); x > 0; x --, ptr += bDepth) {
          ptr[2] = rdr.read_byte();
          ptr[1] = rdr.read_byte();
          ptr[0] = rdr.read_byte();
          ptr[3] = rdr.read_byte();
        }
        break;
    }
  }
  
  if (havemask) {
    for (y = h() - 1; y >= 0; y --) {
      ptr = (uchar *)array + y * w() * d() + 3;
      for (x = w(), bit = 128; x > 0; x --, ptr+=bDepth) {
        if (bit == 128) byte = rdr.read_byte();
        if (byte & bit)
          *ptr = 0;
        else
          *ptr = 255;
        if (bit > 1)
          bit >>= 1;
        else
          bit = 128;
      }
      // Read remaining bytes to align to 32 bits...
      for (temp = (w() + 7) / 8; temp & 3; temp ++)
        rdr.read_byte();
    }
  }
  // File is closed when returning...
}


//
// End of "$Id$".
//