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# Polygonal Gradients

I am working on a project that uses the Juce library to display graphics. So far I have been using the library's API functions to generate linear and radial gradients, however that's the only two types of gradients that this library supports. I am now in need of generating a different type of gradient, one that follows the shape of a regular convex polygon. The key word here is REGULAR, meaning a polygon with all edges of the same length and with all vertices lying on a single circle.

For the case of a pentagon, here is a picture to better show the result I would like to get: http://www.filterforge.com/wiki/index.php/Polygonal_Gradient

For my application, I want to be able to specify a polygonal gradient with any number of edges. (pentagon, hexagon, octagon, etc...)

Given the limitations of the API, the only way I can produce the desired result is to fill a surface matrix pixel by pixel, mathematically calculating the values of the R, G, B, A components for each pixel.

Here is the code I have so far:

``````void render_surface(unsigned char *surface_data,
int width, int height, int linestride,
int num_vertices, t_rgba *color1, t_rgba *color2)
{
const double center_x = 0.5 * width;
const double center_y = 0.5 * height;
const double radius = 0.5 * MIN(width, height);
int x, y;

for (y = height; --y >= 0;) {

uint32_t *line = (uint32_t *)data;
data += linestride;

const double dy = y - center_y;

for (x = width; --x >= 0;) {

const double dx = x - center_x;

double rho = hypot(dx, dy);
rho /= radius;    // normalize radius

// constrain
rho = CLIP(rho, 0.0, 1.0);

// interpolate
double a = color2->alpha + (color1->alpha - color2->alpha) * rho;
double r = color2->red   + (color1->red   - color2->red  ) * rho;
double g = color2->green + (color1->green - color2->green) * rho;
double b = color2->blue  + (color1->blue  - color2->blue ) * rho;

// premultiply alpha
r *= a;
g *= a;
b *= a;

#if LITTLE_ENDIAN
*line++ = ((unsigned int)((256.0 * (1.0 - DBL_EPSILON)) * a) << 24) // alpha
| ((unsigned int)((256.0 * (1.0 - DBL_EPSILON)) * r) << 16) // red
| ((unsigned int)((256.0 * (1.0 - DBL_EPSILON)) * g) <<  8) // green
|  (unsigned int)((256.0 * (1.0 - DBL_EPSILON)) * b);       // blue
#else
*line++ = ((unsigned int)((256.0 * (1.0 - DBL_EPSILON)) * b) << 24) // blue
| ((unsigned int)((256.0 * (1.0 - DBL_EPSILON)) * g) << 16) // green
| ((unsigned int)((256.0 * (1.0 - DBL_EPSILON)) * r) <<  8) // red
|  (unsigned int)((256.0 * (1.0 - DBL_EPSILON)) * a);       // alpha
#endif
}
}
}
``````

The above code produces a radial gradient, the same type of gradient I could produce using one API function. However it seems to be a good starting point to tackle the problem.

surface_data - is a matrix of 8 bit values representing the pixel intensities of the Red, Green, Blue and Alpha components.

num_vertices - is the number of vertices (equally spaced on a single circle) that we want our polygonal gradient to have.

color1 - starting color of the gradient.

color2 - ending color of the gradient.

I would like to know how I can fill a surface in the same fashion, creating a polygonal gradient as opposed to radial.

Thanks for any help.

• Luigi

Rethinking about this problem a little bit... if we consider the origin of our coordinate system the center of the polygon, it boils down to finding an equation such that for any input point in cartesian coordinates, the output is the distance from the closest side of the polygon.

My intuition tells me that there must be some kind of closed form solution because:

for a circle,

``````rho = sqrt(dx*dx + dy*dy);
``````

gives us the radial distance from the center of the circle, which could be considered as a polygon with infinite sides.

For a square,

``````fmax(fabs(dx), fabs(dy));
``````

gives us the Chebyshev distance from the closest side of the square, which could be considered as a polygon with 4 sides.

So, I am thinking that some kind of combination of the two formulas should give the intermediary cases, which would solve the initial problem.

Am I totally off thinking along these lines?

• Luigi
-

## 1 Answer

This is roughly how I'd approach it ...

• Place the center of the polygon at the origin 'O'.
• For a given point 'P' within a given segment of a regular polygon, let the line through 'O' & 'P' be 'Line1' and
• let the line through the outer edge of the containing polygon segment be 'Line2'
• Find the intesection point 'IP' of these 2 lines.

Now the color fraction at P is defined by the distance of P to the origin relative to the distance of IP to the origin.

Edit: I've implemented the algorithm above and this is the output ...

Edit2: Here's the (Delphi) code

``````const
vertical: TFloat = 3.4e38;

function Slope(const pt1, pt2: TFloatPoint): single;
begin
if (pt1.X = pt2.X) then result := vertical
else result := (pt2.Y - pt1.Y)/(pt2.X - pt1.X);
end;
//---------------------------------------------------------------------------

procedure GetLine(const pt1, pt2: TFloatPoint; out m, b: TFloat);
begin
m := Slope(pt1, pt2);
if m = vertical then
b := pt1.X else
b := pt1.Y - m * pt1.X;
end;
//---------------------------------------------------------------------------

function GradientColor(const clr1, clr2: TColor32; fraction: TFloat): TColor32;
begin
if fraction <= 0 then result := clr1
else if fraction >= 1 then result := clr2
else
begin
TColor32Entry(result).B :=
trunc(TColor32Entry(clr2).B * fraction + TColor32Entry(clr1).B * (1-fraction));
TColor32Entry(result).G :=
trunc(TColor32Entry(clr2).G * fraction + TColor32Entry(clr1).G * (1-fraction));
TColor32Entry(result).R :=
trunc(TColor32Entry(clr2).R * fraction + TColor32Entry(clr1).R * (1-fraction));
TColor32Entry(result).A :=
trunc(TColor32Entry(clr2).A * fraction + TColor32Entry(clr1).A * (1-fraction));
end;
end;
//---------------------------------------------------------------------------

function PointInTriangle(const pt, tr1, tr2, tr3: TFloatPoint): boolean;
begin
result := false;
if ((((tr1.Y <= pt.Y) and (pt.Y < tr3.Y)) or
((tr3.Y <= pt.Y) and (pt.Y < tr1.Y))) and
(pt.X < (tr3.X - tr1.X) * (pt.Y - tr1.Y) /
(tr3.Y - tr1.Y) + tr1.X)) then result := not result;
if ((((tr2.Y <= pt.Y) and (pt.Y < tr1.Y)) or
((tr1.Y <= pt.Y) and (pt.Y < tr2.Y))) and
(pt.X < (tr1.X - tr2.X) * (pt.Y - tr2.Y) /
(tr1.Y - tr2.Y) + tr2.X)) then result := not result;
if ((((tr3.Y <= pt.Y) and (pt.Y < tr2.Y)) or
((tr2.Y <= pt.Y) and (pt.Y < tr3.Y))) and
(pt.X < (tr2.X - tr3.X) * (pt.Y - tr3.Y) /
(tr2.Y - tr3.Y) + tr3.X)) then result := not result;
end;
//---------------------------------------------------------------------------

function GetSegmentIndex(vertex: TFloatPoint; vertices: TArrayOfFloatPoint): integer;
var
i, highI: integer;
prev: TFloatPoint;
const
origin: TFloatPoint = (X: 0; Y: 0);
begin
highI := high(vertices);
prev := vertices[highI];
result := -1;
for i := 0 to highI do
begin
if PointInTriangle(vertex, origin, prev, vertices[i]) then
begin
result := i;
break;
end;
prev := vertices[i];
end;
end;
//---------------------------------------------------------------------------

procedure RegularPolygonFill(bmp: TBitmap32; const origin: TPoint;
radius: TFloat; vertexCount: integer; InnerColor, OuterColor: TColor32);
var
i,j,d,q: integer;
dist1,dist2: TFloat;
vert, intersetPt: TFloatPoint;
verts: TArrayOfFloatPoint;
edgeMs, edgeBs: TArrayOfFloat;
angle, angleDiff, m, b: TFloat;
sinAngle, cosAngle: extended;
const
orig: TFloatPoint = (X: 0; Y: 0);
begin
if vertexCount < 3 then exit;
setlength(verts, vertexCount);
setlength(edgeMs, vertexCount); //edge slopes  (ie y = M*x +b)
setlength(edgeBs, vertexCount); //edge offsets (ie y = m*x +B)
angleDiff := pi *2 / vertexCount;
angle := angleDiff;
vert.X := radius; //vert used here as prev vertex
vert.Y := 0;
for i := 0 to vertexCount -1 do
begin
SinCos(angle, sinAngle, cosAngle);
verts[i].X := cosAngle * radius;
verts[i].Y := sinAngle * radius;
GetLine(vert, verts[i], edgeMs[i], edgeBs[i]);
angle := angle + angleDiff;
vert := verts[i];
end;

d := floor(radius);
for i := -d to d do
for j := -d to d do
begin
vert := FloatPoint(i,j);
GetLine(orig, vert, m, b);
q := GetSegmentIndex(vert, verts);
if q < 0 then continue;
//simultaneous equations to find intersection ...
//y = m * x + b; y = edgeMs[q]* x + edgeBs[q];
//edgeMs[q]* x + edgeBs[q] = m * x + b;
//(edgeMs[q] - m) * x = b - edgeBs[q]
//x = (b - edgeBs[q])/(edgeMs[q] - m)
if m = vertical then
begin
intersetPt.X := b;
intersetPt.Y := edgeMs[q]* intersetPt.X + edgeBs[q];
end
else if edgeMs[q] = vertical then
begin
intersetPt.X := edgeBs[q];
intersetPt.Y := m* intersetPt.X + b;
end else
begin
intersetPt.X := (b - edgeBs[q])/(edgeMs[q] - m);
intersetPt.Y := m * intersetPt.X + b;
end;

//get distances from origin of vert and intersetPt ...
dist1 := sqrt(vert.X*vert.X + vert.Y*vert.Y);
dist2 := sqrt(intersetPt.X*intersetPt.X + intersetPt.Y*intersetPt.Y);

bmp.Pixel[i + origin.X, j + origin.Y] :=
GradientColor(InnerColor, OuterColor, dist1/dist2);
end;
end;
``````
-
yes, I haven't tried to directly implement your solution, but at least theoretically it should work. However it involves quite a bit of computation. I was hoping for some kind of closed form equation, simpler and more concise. The input to the equation would be a point in cartesian coordinate and the output the distance from the closest side. – Luigi Castelli Aug 5 '12 at 12:50
For polygons with an even number of sides, this can be sped up considerably by only calculating pixels for one half of the polygon and then mirroring the colors across the midline. Likewise, for polygons with multiples of 4 sides, this can be sped up even more by only calculating pixels for just one quarter of the polygon and then mirroring the pixel colors across the both horizontal and vertical midlines. – Angus Johnson Aug 5 '12 at 12:57
Yes, it looks totally right. Thank you. Would you mind sharing your implementation? I would be very interested in seeing some actual code. (the language doesn't matter) – Luigi Castelli Aug 5 '12 at 13:22
Sure, but I want to tidy it up a bit first. But before that I need some sleep :). – Angus Johnson Aug 5 '12 at 16:24