# Precise subpixel line drawing algorithm (rasterization algorithm)

I need an algorithm which can be (a bit) slower than the Bresenham line drawing algorithm but has to be a lot more exact. With 'exact' I mean: every touched pixel should be printed. No more, but also no less! Which means using a more thick line or similar is not an option as too many pixels will be involved. Also I don't need a graphic framework or similar like it was asked before, I need the algorithm! The application is not really in 'graphics' it is in the geography area where pixels are 'tiles'.

The main problem for me is that I need subpixel precision which means that a line could start at 0.75/0.33 and not just at 0/0 like it is the case for integer values. I tried to create a working solution for the last several hours but cannot make it working - there are too many edge cases.

First I thought an anti-aliased version like the algorithm from Wu should make it but it prints too many pixels (especially for start and end points) and in certain cases it still misses some pixels e.g. for very short lines.

Then I tried to make Bresenham working where I replaced the second 'if' with 'else if' as pointed out here, and it is closer but still not there. Then I tried to move the Bresenham from integer- to float-precision which resulted in an endless loop (as the x,y values jumped over the finish condition `if (y1 == y2 && x1 == x2)`).

I could use the naive line drawing solution but which `delta` should I use? E.g. if I use 0.1 I will still miss some pixels and using smaller values it will probably take too long (and still miss pixels).

A working solution in C/Java/... would be appreciated. At least it should work for octant 1 but a full blown solution would be even nicer.

Update: I came up with the following idea: using the naive line rasterization and you can calculate 4 pixel-candidates for every point. Then check for those 4 pixels if the line really crosses them. But I'm not sure if line/box intersection can be fast enough.

• "every touched pixel should be printed" even if 0.01 of a pixel or less intersects with the line? What shape does both ends of the line take (round, concave, convex, flat)? Jul 10, 2014 at 15:33
• yes, if there is a mathmatical intersection it should be included (of course we can assume the common rounding error stuff). The ends of the line should be flat (no fluff or antialiasing, just the 'mathematical' end) Jul 10, 2014 at 15:42
• what about color? is the line color constant or should be interpolated according to used area of pixel like anti-aliasing does? Jul 10, 2014 at 16:33
• The color is not necessary. It is indeed the same problem MBo pointed in his answer (practical implementation): spatial subdivision and so I only need to know if the 'ray' hits a pixel or not. Jul 10, 2014 at 20:09
• Huh, I see my answer here would probably have fit this question better than that one. I believe my solution is exactly what this question is asking for. Mar 13, 2021 at 5:37

If you need just constant color (not interpolated by used area of pixel) then use DDA:

``````void line_DDA_subpixel(int x0,int y0,int x1,int y1,int col) // DDA subpixel -> thick
{
int kx,ky,c,i,xx,yy,dx,dy;
x1-=x0; kx=0; if (x1>0) kx=+1; if (x1<0) { kx=-1; x1=-x1; } x1++;
y1-=y0; ky=0; if (y1>0) ky=+1; if (y1<0) { ky=-1; y1=-y1; } y1++;
if (x1>=y1)
for (c=x1,i=0;i<x1;i++,x0+=kx)
{
pnt(x0,y0,col); // this is normal pixel the two below are subpixels
c-=y1; if (c<=0) { if (i!=x1-1) pnt(x0+kx,y0,col); c+=x1; y0+=ky; if (i!=x1-1) pnt(x0,y0,col); }
}
else
for (c=y1,i=0;i<y1;i++,y0+=ky)
{
pnt(x0,y0,col); // this is normal pixel the two below are subpixels
c-=x1; if (c<=0) { if (i!=y1-1) pnt(x0,y0+ky,col); c+=y1; x0+=kx; if (i!=y1-1) pnt(x0,y0,col); }
}
}
``````

where:

``````void pnt(int x,int y,int col);
``````

is routine that rasterize pixel `(x,y)` with color col The source is in C++

I think it is strait forward but anyway

DDA use parametric line equation `y=k*x+q` or `x=ky+q` dependent on the difference (if is bigger `x` or `y` difference so there are no holes). The `k` is `dy/dx` or `dx/dy` and the whole division is reduced to substraction+addition inside loop (last line of each loop). This can be easily modified to any number of dimensions (I usually use 7D or more with this). On modern machines is the speed sometimes better then Bresenham (depends on the Platform and usage).

This is how it looks like compared to simple DDA [edit2] double coordinates // originally [edit1]

OK here is new code:

``````void line_DDA_subpixel1(double x0,double y0,double x1,double y1,int col)    // DDA subpixel -> thick
{
int i,n,x,y,xx,yy;
// prepare data n-pixels,x1,y1 is line dx,dy step per pixel
x1-=x0; i=ceil(fabs(x1));
y1-=y0; n=ceil(fabs(y1));
if (n<i) n=i; if (!n) n=1;
x1/=double(n);
y1/=double(n); n++;
// rasterize DDA line
for (xx=x0,yy=y0,i=0;i<=n;i++,x0+=x1,y0+=y1)
{
// direct pixel
pnt(x,y,col);
// subpixels on change in both axises
x=x0; y=y0;
if ((i<n)&&(x!=xx)&&(y!=yy)) { pnt(xx,y,col); pnt(x,yy,col); }
xx=x; yy=y;
}
}
``````

And this is how it looks like: Angle should be in `double` precision now but pnt(x,y,col) is still on integers !!!

[edit3] pixel grid crossing

``````void DDAf_line_subpixel(float x0,float y0,float x1,float y1,int col)    // DDA subpixel -> thick
{
int i,n; float a,a0,a1,aa,b,d;
// end-points
pnt(x0,y0,col);
pnt(x1,y1,col);
// x-axis pixel cross
a0=1; a1=0; n=0;
if (x0<x1) { a0=ceil(x0); a1=floor(x1); d=(y1-y0)/(x1-x0); a=a0; b=y0+(a0-x0)*d; n=fabs(a1-a0); } else
if (x0>x1) { a0=ceil(x1); a1=floor(x0); d=(y1-y0)/(x1-x0); a=a0; b=y1+(a0-x1)*d; n=fabs(a1-a0); }
if (a0<=a1) for (aa=a,i=0;i<=n;i++,aa=a,a++,b+=d) { pnt(aa,b,col); pnt( a,b,col); }
// y-axis pixel cross
a0=1; a1=0; n=0;
if (y0<y1) { a0=ceil(y0); a1=floor(y1); d=(x1-x0)/(y1-y0); a=a0; b=x0+(a0-y0)*d; n=fabs(a1-a0); } else
if (y0>y1) { a0=ceil(y1); a1=floor(y0); d=(x1-x0)/(y1-y0); a=a0; b=x1+(a0-y1)*d; n=fabs(a1-a0); }
if (a0<=a1) for (aa=a,i=0;i<=n;i++,aa=a,a++,b+=d) { pnt(b,aa,col); pnt(b, a,col); }
}
``````

Finally had some time for this so I tweaked DDA a little but id lead to many `if`s so I change rasterization quite a bit. Now all pixel grid crossing (intersections) are computed and then for each the right sub-pixel is added. This is how it looks like (no wrong sub-pixels): For each `x` or `y` grid lines is the first cross point computed `(a,b)` and `step` is in one axis `1` pixel and in second the rest according to `dy/dx` or `dx/dy`. After this the for loop fill the sub-pixels ...

• if area percentage is needed then it can be derived from the state of variable c but I newer used it because I do not need it. Jul 10, 2014 at 17:14
• This is a good specific-case algorithm for what the OP is looking for, but AFAICT this doesn't address the extremely likely cases where the line start and end coordinates are of non-integer values. Jul 10, 2014 at 19:05
• Will it work if I replace the int arguments with e.g. double? Jul 10, 2014 at 19:42
• @Karussell yes but then it will be faster to make the dy/dx or dx/dy in classic manner. and also then you should add the subpixel point via if ((x-floor(x))>0.0) ... and the same goes for y Jul 10, 2014 at 23:26
• @Karussell I would left it on integers as is and add these 2 subpoints per each endpoint if needed. Jul 10, 2014 at 23:29

If your line is thin and pixels are rectangular (square): then consider using of voxel grid traversal algorithms, for example, see article "Fast Voxel Traversal Algorithm..." by Woo and Amanatides.

Practical implementation (in grid traversal section)

Proper initialization for X-coordinate variables (the same for Y)

``````  DX = X2 - X1
tDeltaX = GridCellWidth / DX
tMaxX = tDeltaX * (1.0 - Frac(X1 / GridCellWidth))
//Frac if fractional part of float, for example, Frac(1.3) = 0.3
``````

• I implemented your java code (github link) in python for prototyping. And it didn't work for all cases (all combinations of start and end points). My cells are centered on integer numbers, my start and end points are arbitrary float values. I changed the following and it worked: `if stepX < 0: maxX = deltaX * (0.5 + (tmp - np.round(tmp))); else: maxX = deltaX * (0.5 - (tmp - np.round(tmp)));` Same for maxY using stepY. Added `;` as line ending sign in the code Mar 17, 2016 at 10:12