# I need a pixel-perfect triangle fill algorithm to avoid aliasing artifacts

I'm assisting someone with user interface code to visualise a mathematical image analysis. During this process we'll be segmenting part of a 2D shape into triangles, and filling some of these triangles in on the UI.

We're looking for a fill algorithm which guarantees that if two triangles share an edge (specifically, if any two vertices of the triangles are identical), then regardless of drawing order and aliasing there will be not be blank, undrawn pixels on the line between the two. (It's alright if some pixels are drawn twice.) The result should look OK under arbitrary scaling. Some triangles may be extremely thin slivers in places, down to 1 pixel wide.

Ideally it should also be a reasonably efficient fill algorithm!

Anti-aliasing will not be used in triangle rendering, as the final image needs to be 1-bit depth.

The context is an image-recognition application, so all vertex coordinates will be accurate to one pixel.

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Can't you simply draw the triangles with a default filling procedure (of your library) and then do a single post-processing operation than fills the missing pixels? –  elmes Jun 21 '12 at 13:55
@elmes: That would be an acceptable approach, but that still leaves 'good algorithm for identifying the missing pixels' as the question. (I am hoping that somebody who knows more about graphics than I do knows a triangle-rasterization algorithm that prevents it from being a problem in the first place.) –  Tynam Jun 21 '12 at 13:59
Well, do you know the color of the background? Even if you don't, you can try a simple erode / dilate post-processing. –  elmes Jun 21 '12 at 14:04
We'll either have white pixels on a black background, or vice-versa, on a per-image basis (we can invert trivially, of course). However, we don't want to erode / dilate (or similar), because we don't want to alter the exterior edge where the triangles are not adjacent. –  Tynam Jun 21 '12 at 14:07
Well, I don't know of any 'smart' algorithm .. maybe others will help you more ;-) I'd try a conditional dilation though. –  elmes Jun 21 '12 at 14:12

Given the requirements, it looks like there's a simple solution.

First, rasterize the triangle edges. You can use the Bresenham's line drawing algorithm for that (as in the code below) or anything that works. Then fill in the area in-between. This will work with arbitrarily thin triangles.

To make sure there are no gaps irrespective of the order in which triangles are drawn and irrespective of the order of the vertices supplied to the triangle-drawing code you want to rasterize shared edges in the same way in the triangles sharing an edge. Same way means the same pixels every time.

To guarantee that every time you get the same pixels from the same pairs of vertex coordinates you basically want to establish a fixed order, that is, establish a rule that would always choose the same one vertex out of the two given irrespective of the order in which they are given.

One simple way to enforce this order is to treat your line (triangle edge) as a 2-d vector and flip its direction if it points in the direction of negative y's or is parallel to the x axis and points in the direction of negative x's. Time for some ASCII art! :)

``````      3   2   1
\  |  /
\ | /
\|/
4 --------+--------- 0
/|\
/ | \
/  |  \
5   6   7

4 -> 0
5 -> 1
6 -> 2
7 -> 3
``````

See, here line segment, say, 1 and line segment 5 are really the same kind of thing, the only difference is the direction from the endpoint at the origin to the other endpoint. So we reduce these cases in half by turning segments 4 through 7 into segments 0 through 3 and get rid of the direction ambiguity. IOW, we choose to go in the direction of increasing y's OR, if y's are the same on the edge, in the direction of increasing x's.

Here's how you could do it in code:

``````#include <stddef.h>
#include <limits.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <time.h>

#define SCREEN_HEIGHT 22
#define SCREEN_WIDTH  78

// Simulated frame buffer
char Screen[SCREEN_HEIGHT][SCREEN_WIDTH];

void SetPixel(long x, long y, char color)
{
if ((x < 0) || (x >= SCREEN_WIDTH) ||
(y < 0) || (y >= SCREEN_HEIGHT))
{
return;
}

if (Screen[y][x] == ' ')
Screen[y][x] = color;
else
Screen[y][x] = '*';
}

void Visualize(void)
{
long x, y;

for (y = 0; y < SCREEN_HEIGHT; y++)
{
for (x = 0; x < SCREEN_WIDTH; x++)
{
printf("%c", Screen[y][x]);
}

printf("\n");
}
}

typedef struct
{
long x, y;
unsigned char color;
} Point2D;

// min X and max X for every horizontal line within the triangle
long ContourX[SCREEN_HEIGHT][2];

#define ABS(x) ((x >= 0) ? x : -x)

// Scans a side of a triangle setting min X and max X in ContourX[][]
// (using the Bresenham's line drawing algorithm).
void ScanLine(long x1, long y1, long x2, long y2)
{
long sx, sy, dx1, dy1, dx2, dy2, x, y, m, n, k, cnt;

sx = x2 - x1;
sy = y2 - y1;

/*
3   2   1
\  |  /
\ | /
\|/
4 --------+--------- 0
/|\
/ | \
/  |  \
5   6   7

4 -> 0
5 -> 1
6 -> 2
7 -> 3
*/
if (sy < 0 || sy == 0 && sx < 0)
{
k = x1; x1 = x2; x2 = k;
k = y1; y1 = y2; y2 = k;
sx = -sx;
sy = -sy;
}

if (sx > 0) dx1 = 1;
else if (sx < 0) dx1 = -1;
else dy1 = 0;

if (sy > 0) dy1 = 1;
else if (sy < 0) dy1 = -1;
else dy1 = 0;

m = ABS(sx);
n = ABS(sy);
dx2 = dx1;
dy2 = 0;

if (m < n)
{
m = ABS(sy);
n = ABS(sx);
dx2 = 0;
dy2 = dy1;
}

x = x1; y = y1;
cnt = m + 1;
k = n / 2;

while (cnt--)
{
if ((y >= 0) && (y < SCREEN_HEIGHT))
{
if (x < ContourX[y][0]) ContourX[y][0] = x;
if (x > ContourX[y][1]) ContourX[y][1] = x;
}

k += n;
if (k < m)
{
x += dx2;
y += dy2;
}
else
{
k -= m;
x += dx1;
y += dy1;
}
}
}

void DrawTriangle(Point2D p0, Point2D p1, Point2D p2)
{
long y;

for (y = 0; y < SCREEN_HEIGHT; y++)
{
ContourX[y][0] = LONG_MAX; // min X
ContourX[y][1] = LONG_MIN; // max X
}

ScanLine(p0.x, p0.y, p1.x, p1.y);
ScanLine(p1.x, p1.y, p2.x, p2.y);
ScanLine(p2.x, p2.y, p0.x, p0.y);

for (y = 0; y < SCREEN_HEIGHT; y++)
{
if (ContourX[y][1] >= ContourX[y][0])
{
long x = ContourX[y][0];
long len = 1 + ContourX[y][1] - ContourX[y][0];

// Can draw a horizontal line instead of individual pixels here
while (len--)
{
SetPixel(x++, y, p0.color);
}
}
}
}

int main(void)
{
Point2D p0, p1, p2, p3;

// clear the screen
memset(Screen, ' ', sizeof(Screen));

// generate random triangle coordinates

srand((unsigned)time(NULL));

// p0 - p1 is going to be the shared edge,
// make sure the triangles don't intersect
for (;;)
{
p0.x = rand() % SCREEN_WIDTH;
p0.y = rand() % SCREEN_HEIGHT;

p1.x = rand() % SCREEN_WIDTH;
p1.y = rand() % SCREEN_HEIGHT;

p2.x = rand() % SCREEN_WIDTH;
p2.y = rand() % SCREEN_HEIGHT;

p3.x = rand() % SCREEN_WIDTH;
p3.y = rand() % SCREEN_HEIGHT;

{
long vsx = p0.x - p1.x;
long vsy = p0.y - p1.y;
long v1x = p0.x - p2.x;
long v1y = p0.y - p2.y;
long v2x = p0.x - p3.x;
long v2y = p0.y - p3.y;
long z1 = vsx * v1y - v1x * vsy;
long z2 = vsx * v2y - v2x * vsy;
// break if p2 and p3 are on the opposite sides of p0-p1
if (z1 * z2 < 0) break;
}
}

printf("%ld:%ld %ld:%ld %ld:%ld %ld:%ld\n\n",
p0.x, p0.y,
p1.x, p1.y,
p2.x, p2.y,
p3.x, p3.y);

// draw the triangles

p0.color = '-';
DrawTriangle(p0, p3, p1);
p1.color = '+';
DrawTriangle(p1, p2, p0);

Visualize();

return 0;
}
``````

Sample output:

``````30:10 5:16 16:6 59:17

+++
++++++++
++++++++++++
+++++++++++++++++
+++++++++++++++****---
+++++++++++++****-----------
++++++++++****-------------------
++++++*****----------------------------
+++****-------------------------------------
****---------------------------------------------
*-----------------------------------------------------
-
``````

Legend:

• "+" - pixels of triangle 1
• "-" - pixels of triangle 2
• "*" - pixels of the edge shared between triangles 1 and 2

Beware that even though there will be no unfilled gaps (pixels), the triangle whose pixels (on the shared edge) get overwritten (because of the other triangle drawn on top of it) may show up as disjoint or awkwardly shaped if it's too thin. Example:

``````2:20 12:8 59:15 4:17

*++++++
*+++++++++++++
*+++++++++++++++++++++
-*++++++++++++++++++++++++++++
-*++++++++++++++++++++++++++++++++++++
*+++++++++++++++++++++++++++++++++++++++++++
*+++++++++++++++++++++++++++++++++++++++++++++++++++
*+++++++++++++++++++++++++++++++++++++++++++++++++++++
*+++++++++++++++++++++++++++++++++++++++++++
-*+++++++++++++++++++++++++++++++
-*+++++++++++++++++++++
*++++++++++
*
``````
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+1 for extensive ASCII and a thorough explanation of even the simplest concepts. We'll probably do something just like this. (Because many of our triangles are thin slices, disjoint or awkward shapes are inevitable no matter what approach we use; that's fine as long as our fill picks something appropriate and doesn't leave gaps.) –  Tynam Jun 21 '12 at 23:04
Really a useful answer, found 1 bug though: FIrst line reading "else dy1 = 0;" should be "else dx1 = 0;" instead –  philipp Jan 29 at 14:45

Your concern about adjacent triangles is a valid one. If two triangles share an edge, you want to be sure that every pixel along that edge "belongs" exclusively to one triangle or the other. If one of those pixels doesn't belong to either triangle, you have a gap. If it belongs to both triangles, you have overdraw (which is inefficient) and the color might depend on the order the triangles are rendered (which may not be deterministic).

Since you're not using anti-aliasing, this actually isn't too hard. It's not so much a smart algorithm you need as a careful implementation.

The typical way to rasterize a triangle is to compute horizontal segments that are part of the triangle from the top to the bottom. You do this by keeping track of the current left and right edges, and essentially doing an x-intercept calculation for each edge at each scanline. It can also be done with two Bresenhem-style line-drawing algorithms running together. Effectively, the rasterization amounts to several calls to a function that draws a horizontal line segment at some scanline `y` from some left coordinate `x0` to some right coordinate `x1`.

``````void DrawHLine(int y, int x0, int x1);
``````

Typically what's done is to make sure the rasterizer rounds off the x-intercepts in a consistent manner, so that the x-coordinates are computed consistently regardless of whether they are part of the right edge of one triangle or the left edge of the adjacent triangle. This guarantees that every pixel along the shared edge will belong to both triangles.

We resolve the double-ownership by tweaking `DrawHLine` so that it fills the pixels from `x0` inclusive up to `x1` exclusive. So all those doubly-owned pixels on the shared edge are defined to belong to the triangle on the right of the shared edge.

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+1. I did pretty much the same in my answer. –  Alexey Frunze Jun 21 '12 at 20:18

What you are looking for is a `floodfill` algorithm.

You can google 'floodfill-algorithm' for more.

Maybe this site[Shader-Based Wireframe Drawing] can offer some more ideas.

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Simple seed-based flood fills are out, because some triangles will have angles acute enough to run into the 'trapped pixels near the point' problem. (Also, finding an interior start pixel reliably can be an issue in itself in angled 'slim' triangles.) However, your link to the quickfill discussion is interesting; we'll take a proper look. –  Tynam Jun 21 '12 at 14:39
@Tynam: It could be possible to use the pixel-scanning technique(s) to examine interesting areas for unfilled pixels, e.g. very acute angles or pixel-wide triangles: if the unfilled pixel lies within at least one boundary, then it should be filled. That could mean doing a line-scan of the entire triangle for unfilled pixels (scan lines starting from an arbitrary side and parallel to it with end-points inclusive of the other two sides should do the trick). –  slashmais Jun 21 '12 at 14:53

It's not the most efficient, but you could loop over a square containing the triangle and test if each pixel is within the triangle.

Pseudocode:

``````for(x : minX -> maxX)
for(y : minY -> maxY)
if(triangle.contains(x,y))
drawPixel(x,y);
``````

Where minX is the minimum X coordinate between the three vertices and similarly for maxX, minY and maxY.

For a faster algorithm you could do some quick and dirty filling (e.g. slashmais flood filling) first and then do this for the pixels around the edges.

The point-in-triangle test is described here.

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