# Drawing N-width lines?

Given a series of points, how could I calculate the vector for that line 5 pixels away? Ex: Given:

\
\
\

How could I find the vector for

\  \
\  \
\  \

The ones on the right.

I'm trying to figure out how programs like Flash can make thick outlines.

Thanks

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A vector is always, per definition, a nice straight line... It's even an infinitely long, nice, straight line. Also, five pixels in what direction? To the right? Along the normal to the first line? – Jakob Borg Jun 5 '10 at 20:15
Is this homework or personal project? – Heath Hunnicutt Jun 5 '10 at 20:15
What would you want to happen if the original series of line segments was not simply a vertical line? – SamB Jun 5 '10 at 20:17
Personal project, I'm making a vector drawing application – jmasterx Jun 5 '10 at 20:17
Your example isn't a series of points, it starts with a line. Can you clarify? – user97370 Jun 5 '10 at 20:18

A thick line is a polygon. (Let's forget about antialiasing for now)

start = line start = vector(x1, y1)
end = line end = vector(x2, y2)
dir = line direction = end - start = vector(x2-x1, y2-y1)
ndir = normalized direction = dir*1.0/length(dir)
perp = perpendicular to direction = vector(dir.x, -dir.y)
nperp = normalized perpendicular = perp*1.0/length(perp)

perpoffset = nperp*w*0.5
diroffset = ndir*w*0.5

(You can easily remove one normalization and calculate one of the offsets by taking perpendicular from the other)

p0, p1, p2, p3 = polygon points:
p0 = start + perpoffset - diroffset
p1 = start - perpoffset - diroffset
p2 = end + perpoffset + diroffset
p3 = end - perpoffset + diroffset

P.S. You're the last person I ever going to explain this stuff to. Things like these should be understood on intuitive level.

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+1 for the pretty graphics. – Thomas Matthews Jun 5 '10 at 21:06
Thank you very much, I really appreciate this explanation, despite taking Alegebra 1 and 2 and Physics in high school I still have trouble with these things... – jmasterx Jun 5 '10 at 21:15

The way to do with a straight line is to find the line perpendicular (N) to the original line, take a 5 pixels step in that direction and then find the perpendicular to the perpendicular in that point

|     |
--+-----+---N
|     |
|     |

The way to do it with a non straight line is to approximate it with many straight lines or if you have the analytic representation of the line, to find some sort of analytic solution in a similar manner to the one of the straight line.

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Try this untested pseudo-code:

# Calculate the "Rise" and "run" (slope) of your input line, then
# call this function, which returns offsets of x- and y-intercept
# for the parallel line.  Obviously the slope of the parallel line

# returns (delta_x, delta_y) to be added to intercepts.
negate = other_side ? -1 : 1
if rise == 0:
# horizontal line; parallel is vertically away
return (0, negate * distance)
elif run == 0:
# vertical line; parallel is horizontally away
return (negate * distance, 0)
else:
# a perpendicular radius is - run / rise slope with length
# run^2 + rize^2 = length  ^ 2
nrml = sqrt(run*run + rise*rise)
return (negate * -1 * run / nrml, negate * rise/nrml)

As SigTerm shows in his nice diagram, you will want to get the lines on either side of the intended line: so pass in thickness/2 for distance and call twice, once with other_side=true, and draw a thickness centered on the 'abstract line'.

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You will need to have some math background.

Start by understanding the line (linear equations and linear functions) what is a parallel and benefit from looking up geometric transformations.

After that you will understand SigTerm's answer...

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