/// <summary>
/// Transform linear RGB values to nonlinear RGB values. Rec.
/// 709 is ITU-R Recommendation BT. 709 (1990) ``Basic
/// Parameter Values for the HDTV Standard for the Studio and
/// for International Programme Exchange'', formerly CCIR Rec.
/// 709. For details see
///
/// http://www.poynton.com/ColorFAQ.html
/// http://www.poynton.com/GammaFAQ.html
///
/// </summary>
/// <param name="cs"></param>
/// <param name="c"></param>
static void gamma_correct(ColourSystem cs, ref double c)
{
double gamma;
gamma = cs.Gamma;
if (gamma == ColourSystems.GAMMA_REC709)
{
// Rec. 709 gamma correction.
double cc = 0.018;
if (c < cc)
{
c *= ((1.099 * Math.Pow(cc, 0.45)) - 0.099) / cc;
}
else
{
c = (1.099 * Math.Pow(c, 0.45)) - 0.099;
}
}
else
{
// Nonlinear colour = (Linear colour)^(1/gamma)
c = Math.Pow(c, 1.0 / gamma);
}
}
public static Color FromTemp(this Color col, double temp, ColourSystem cs)
{
double r, g, b;
RgbFromTemp(temp, out r, out g, out b, cs);
return(Color.FromArgb(255, (int)r * 255, (int)r * 255, (int)r * 255));
}
static void gamma_correct_rgb(ColourSystem cs, ref double r, ref double g, ref double b)
{
gamma_correct(cs, ref r);
gamma_correct(cs, ref g);
gamma_correct(cs, ref b);
}
/// <summary>
/// Given an additive tricolour system CS, defined by the CIE x
/// and y chromaticities of its three primaries (z is derived
/// trivially as 1-(x+y)), and a desired chromaticity (XC, YC,
/// ZC) in CIE space, determine the contribution of each
/// primary in a linear combination which sums to the desired
/// chromaticity. If the requested chromaticity falls outside
/// the Maxwell triangle (colour gamut) formed by the three
/// primaries, one of the r, g, or b weights will be negative.
///
/// Caller can use constrain_rgb() to desaturate an
/// outside-gamut colour to the closest representation within
/// the available gamut and/or norm_rgb to normalise the RGB
/// components so the largest nonzero component has value 1.
/// </summary>
/// <param name="cs"></param>
/// <param name="xc"></param>
/// <param name="yc"></param>
/// <param name="zc"></param>
/// <param name="r"></param>
/// <param name="g"></param>
/// <param name="b"></param>
public static void XyzToRgb(ColourSystem cs,
double xc, double yc, double zc,
out double r, out double g, out double b)
{
double xr, yr, zr, xg, yg, zg, xb, yb, zb;
double xw, yw, zw;
double rx, ry, rz, gx, gy, gz, bx, by, bz;
double rw, gw, bw;
xr = cs.Red.X;
yr = cs.Red.Y;
zr = 1 - (xr + yr);
xg = cs.Green.X;
yg = cs.Green.Y;
zg = 1 - (xg + yg);
xb = cs.Blue.X;
yb = cs.Blue.Y;
zb = 1 - (xb + yb);
xw = cs.White.X;
yw = cs.White.Y;
zw = 1 - (xw + yw);
// xyz -> rgb matrix, before scaling to white.
rx = (yg * zb) - (yb * zg);
ry = (xb * zg) - (xg * zb);
rz = (xg * yb) - (xb * yg);
gx = (yb * zr) - (yr * zb);
gy = (xr * zb) - (xb * zr);
gz = (xb * yr) - (xr * yb);
bx = (yr * zg) - (yg * zr);
by = (xg * zr) - (xr * zg);
bz = (xr * yg) - (xg * yr);
// White scaling factors.
// Dividing by yw scales the white luminance to unity, as conventional.
rw = ((rx * xw) + (ry * yw) + (rz * zw)) / yw;
gw = ((gx * xw) + (gy * yw) + (gz * zw)) / yw;
bw = ((bx * xw) + (by * yw) + (bz * zw)) / yw;
// xyz -> rgb matrix, correctly scaled to white.
rx = rx / rw;
ry = ry / rw;
rz = rz / rw;
gx = gx / gw;
gy = gy / gw;
gz = gz / gw;
bx = bx / bw;
by = by / bw;
bz = bz / bw;
// rgb of the desired point
r = (rx * xc) + (ry * yc) + (rz * zc);
g = (gx * xc) + (gy * yc) + (gz * zc);
b = (bx * xc) + (by * yc) + (bz * zc);
}
private static void RgbFromTemp(double temp, out double r, out double g, out double b, ColourSystem cs)
{
double x, y, z;
Kernel.SpectrumToXyz((double waveLength) => { return(Kernel.BlackBodySpectrum(waveLength, temp)); }, out x, out y, out z);
Kernel.XyzToRgb(cs, x, y, z, out r, out g, out b);
if (Kernel.ConstrainRgb(ref r, ref g, ref b))
{
Kernel.NormRgb(ref r, ref g, ref b);
}
else
{
Kernel.NormRgb(ref r, ref g, ref b);
}
}
