#define myRGB(r,g,b) ((wxUint32)r<<16|(wxUint32)g<<8|(wxUint32)b)
-static rgbRecord theRGBRecords[] =
+static const rgbRecord theRGBRecords[] =
{
{"aliceblue", myRGB(240, 248, 255)},
{"antiquewhite", myRGB(250, 235, 215)},
{"yellowgreen", myRGB(50, 216, 56)},
{NULL, myRGB(0, 0, 0)}
};
-static int numTheRGBRecords = 235;
+static const int numTheRGBRecords = 235;
static unsigned char ParseHexadecimal(char digit1, char digit2)
{
int count;
unsigned width, height, colors_cnt, chars_per_pixel;
size_t i, j, i_key;
- wxChar key[64];
+ char key[64];
const char *clr_def;
- bool hasMask;
wxXPMColourMap clr_tbl;
wxXPMColourMap::iterator it;
wxString maskKey;
+ wxString keyString;
/*
* Read hints and initialize structures:
// 8bit RGB...
wxCHECK_MSG(chars_per_pixel < 64, wxNullImage, wxT("XPM colormaps this large not supported."));
- if ( !img.Create(width, height) )
+ if (!img.Create(width, height, false))
return wxNullImage;
- img.SetMask(false);
- key[chars_per_pixel] = wxT('\0');
- hasMask = false;
+ key[chars_per_pixel] = '\0';
/*
* Create colour map:
}
for (i_key = 0; i_key < chars_per_pixel; i_key++)
- key[i_key] = (wxChar)xmpColLine[i_key];
+ key[i_key] = xmpColLine[i_key];
clr_def = ParseColor(xmpColLine + chars_per_pixel);
if ( clr_def == NULL )
return wxNullImage;
}
+ keyString = key;
if ( isNone )
- {
- img.SetMask(true);
- img.SetMaskColour(255, 0, 255);
- clr_data.R =
- clr_data.B = 255;
- clr_data.G = 0;
- hasMask = true;
- maskKey = key;
- }
+ maskKey = keyString;
- clr_tbl[key] = clr_data;
+ clr_tbl[keyString] = clr_data;
}
- /*
- * Modify colour entries with RGB = (255,0,255) to (255,0,254) if
- * mask colour is present (so that existing pixels with (255,0,255)
- * magenta colour are not incorrectly made transparent):
- */
- if (hasMask)
+ // deal with the mask: we must replace pseudo-colour "None" with the mask
+ // colour (which can be any colour not otherwise used in the image)
+ if (!maskKey.empty())
{
- for (it = clr_tbl.begin(); it != clr_tbl.end(); ++it)
+ wxLongToLongHashMap rgb_table;
+ long rgb;
+ const size_t n = clr_tbl.size();
+ wxXPMColourMap::const_iterator iter = clr_tbl.begin();
+ for (i = 0; i < n; ++i, ++iter)
{
- if (it->second.R == 255 && it->second.G == 0 &&
- it->second.B == 255 &&
- it->first != maskKey)
- {
- it->second.B = 254;
- }
+ const wxXPMColourMapData& data = iter->second;
+ rgb = (data.R << 16) + (data.G << 8) + data.B;
+ rgb_table[rgb];
+ }
+ for (rgb = 0; rgb <= 0xffffff && rgb_table.count(rgb); ++rgb)
+ ;
+ if (rgb > 0xffffff)
+ {
+ wxLogError(_("XPM: no colors left to use for mask!"));
+ return wxNullImage;
}
+
+ wxXPMColourMapData& maskData = clr_tbl[maskKey];
+ maskData.R = wxByte(rgb >> 16);
+ maskData.G = wxByte(rgb >> 8);
+ maskData.B = wxByte(rgb);
+
+ img.SetMaskColour(maskData.R, maskData.G, maskData.B);
}
/*
for (i_key = 0; i_key < chars_per_pixel; i_key++)
{
- key[i_key] = (wxChar)xpmImgLine[chars_per_pixel * i + i_key];
+ key[i_key] = xpmImgLine[chars_per_pixel * i + i_key];
}
- entry = clr_tbl.find(key);
+ keyString = key;
+ entry = clr_tbl.find(keyString);
if ( entry == end )
{
wxLogError(_("XPM: Malformed pixel data!"));
// each remaining pixel if we don't bail out
return wxNullImage;
}
- else
- {
- img_data[0] = entry->second.R;
- img_data[1] = entry->second.G;
- img_data[2] = entry->second.B;
- }
+
+ img_data[0] = entry->second.R;
+ img_data[1] = entry->second.G;
+ img_data[2] = entry->second.B;
}
}