For sure use the ScanLine property to access bitmap pixels since you're working with a large array of pixels where the Pixels access is slow. For replacing colors of your choice with support for 24-bit and 32-bit bitmaps, I would use something like this:
procedure ReplaceColor(ABitmap: TBitmap; ASource, ATarget: TColor);
type
TRGBBytes = array[0..2] of Byte;
var
I: Integer;
X: Integer;
Y: Integer;
Size: Integer;
Pixels: PByteArray;
SourceColor: TRGBBytes;
TargetColor: TRGBBytes;
const
TripleSize = SizeOf(TRGBBytes);
begin
case ABitmap.PixelFormat of
pf24bit: Size := TripleSize;
pf32bit: Size := SizeOf(TRGBQuad);
else
raise Exception.Create('Bitmap must be 24-bit or 32-bit format!');
end;
for I := 0 to TripleSize - 1 do
begin
// fill the array of bytes with color channel values in BGR order,
// the same would do for the SourceColor from ASource parameter:
// SourceColor[0] := GetBValue(ASource);
// SourceColor[1] := GetGValue(ASource);
// SourceColor[2] := GetRValue(ASource);
// but this is (just badly readable) one liner
SourceColor[I] := Byte(ASource shr (16 - (I * 8)));
// the same do for the TargetColor array from the ATarget parameter
TargetColor[I] := Byte(ATarget shr (16 - (I * 8)));
end;
for Y := 0 to ABitmap.Height - 1 do
begin
// get a pointer to the currently iterated row pixel byte array
Pixels := ABitmap.ScanLine[Y];
// iterate the row horizontally pixel by pixel
for X := 0 to ABitmap.Width - 1 do
begin
// now imagine, that you have an array of bytes in which the groups of
// bytes represent a single pixel - e.g. the used Pixels array for the
// first 2 pixels might look like this for 24-bit and 32-bit bitmaps:
// Pixels [0][1][2] [3][4][5]
// 24-bit B G R B G R
// Pixels [0][1][2][3] [4][5][6][7]
// 32-bit B G R A B G R A
// from the above you can see that you'll need to multiply the current
// pixel iterator by the count of color channels to point to the first
// (blue) color channel in that array; and that's what that (X * Size)
// is for here; X is a pixel iterator, Size is size of a single pixel:
// X * 3 (0 * 3) (1 * 3)
// ? ?
// Pixels [0][1][2] [3][4][5]
// 24-bit B G R B G R
// X * 4 (0 * 4) (1 * 4)
// ? ?
// Pixels [0][1][2][3] [4][5][6][7]
// 32-bit B G R A B G R A
// so let's compare a BGR value starting at the (X * Size) position of
// the Pixels array with the SourceColor array and if it matches we've
// found the same colored pixel, if so then...
if CompareMem(@Pixels[(X * Size)], @SourceColor, TripleSize) then
// copy the TargetColor color byte array values to that BGR position
// (in other words, replace the color channel bytes there)
Move(TargetColor, Pixels[(X * Size)], TripleSize);
end;
end;
end;
And the usage:
procedure TForm1.Button1Click(Sender: TObject);
var
Bitmap: TBitmap;
begin
Bitmap := TBitmap.Create;
try
Bitmap.LoadFromFile('d:Image.bmp');
ReplaceColor(Bitmap, clWhite, clBlack);
Image1.Picture.Assign(Bitmap);
finally
Bitmap.Free;
end;
end;
For pure GDI and bitmaps having at most 256 colors you might use the CreateMappedBmp function.
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