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I have currently the following line in my program. I have two other whole number variables, x and y.

I wish to see if this new point(x, y) is on this line. I have been looking at the following thread:

Given a start and end point, and a distance, calculate a point along a line

I've come up with the following:

if(x >= x1 && x <= x2 && (y >= y1 && y <= y2 || y <= y1 && y >= y2))
    float vx = x2 - x1;
    float vy = y2 - y1;
    float mag = sqrt(vx*vx + vy*vy);
    // need to get the unit vector (direction)
    float dvx = vx/mag; // this would be the unit vector (direction) x for the line
    float dvy = vy/mag; // this would be the unit vector (direction) y for the line

    float vcx = x - x1;
    float vcy = y - y1;
    float magc = sqrt(vcx*vcx + vcy*vcy);
    // need to get the unit vector (direction)
    float dvcx = vcx/magc; // this would be the unit vector (direction) x for the point
    float dvcy = vcy/magc; // this would be the unit vector (direction) y for the point

    // I was thinking of comparing the direction of the two vectors, if they are the same then the point must lie on the line?
    if(dvcx == dvx && dvcy == dvy)
        // the point is on the line!

It doesn't seem to be working, or is this idea whack?

  • 2
    Its in 2D, why not simply put (x,y) in equation of line obtained from (x1,y1) and (x2,y2) ? – P0W Nov 10 '14 at 17:43
  • Is (x, y) a point (as the title indicates) or a vector (as the question seems to indicate)? The question only really seems to make much sense if it's a point, but perhaps you're talking about whether the lines defined by two vectors intersect? – Jerry Coffin Nov 10 '14 at 17:45
  • First, please state your conditions/assumptions. If you are dealing with floats, you must consider floating point inaccuracies. Direct math into formulas won't work. – dornhege Nov 10 '14 at 17:46
  • @JerryCoffin a point! apologize for the inconsistent notation. – Karl Morrison Nov 10 '14 at 17:47
  • 2
    See this – P0W Nov 10 '14 at 17:49

Floating point numbers have a limited precision, so you'll get rounding errors from the calculations, with the result that values that should mathematically be equal will end up slightly different.

You'll need to compare with a small tolerance for error:

if (std::abs(dvcx-dvx) < tolerance && std::abs(dvcy-dvy) < tolerance)
    // the point is (more or less) on the line!

The hard part is choosing that tolerance. If you can't accept any errors, then you'll need to use something other than fixed-precision floating point values - perhaps integers, with the calculations rearranged to avoid division and other inexact operations.

In any case, you can do this more simply, without anything like a square root. You want to find out if the two vectors are parallel; they are if the vector product is zero or, equivalently, if they have equal tangents. So you just need

if (vx * vcy == vy * vcx)  // might still need a tolerance for floating-point
    // the point is on the line!

If your inputs are integers, small enough that the multiplication won't overflow, then there's no need for floating-point arithmetic at all.

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  • To elaborate, the x1, y1 and x2, y2 are integers! – Karl Morrison Nov 10 '14 at 17:46
  • @KarlMorrison: In that case, you should be able to avoid floating-point shenanigans altogether. See my updated answer. – Mike Seymour Nov 10 '14 at 17:57

An efficient way to solve this problem is to use the signed area of a triangle. When the signed area of the triangle created by points {x1,y1}, {x2,y2}, and {x,y} is near-zero, you can consider {x,y} to be on the line. As others have mentioned, picking a good tolerance value is an important part of this if you are using floating point values.

bool isPointOnLine (xy p1, xy p2, xy p3) // returns true if p3 is on line p1, p2
    xy va = p1 - p2;
    xy vb = p3 - p2;
    area = va.x * vb.y - va.y * vb.x;
    if (abs (area) < tolerance)
        return true;
    return false;

This will let you know if {x,y} lies on the line, but it will not determine if {x,y} is contained by the line segment. To do that, you would also need to check {x,y} against the bounds of the line segment.

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First you need to calculate the equation of your line. Then see if this equation holds true for the values of x and y that you have. To calculate the equation of your line, you need to work out where it croses the y-axis and what its gradient is. The equation will be of the form y=mx+c where m is the gradient and c is the 'intercept' (where the line crosses the y-axis).

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For float values, don't use == but instead test for small difference:

if (fabs(dvcx-dvx) < delta && fabs(dvcy-dvy) < delta)

Also, you don't really need the unit vector, just the tangent:

float originalTangent = (y2 - y1) / (x2 - x1);
float newTangent = (y - y1) / (x - x1);
if (fabs(newTangent - originalTangent) < delta) { ... }

(delta should be some small number that depends on the accuracy you are expecting.)

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Given that (x, y) is actually a point, the job seems a bit simpler than you're making it.

You probably want to start by checking for a perfectly horizontal or vertical line. In those cases, you just check whether x falls between x1 and x2 (or y between y1 and y2 for vertical).

Otherwise you can use linear interpolation on x and see if it gives you the correct value for y (within some possible tolerance for rounding). For this, you'd do something like:

slope = (y2-y1)/(x2-x1);
if (abs(slope * (x - x1) - y) < tolerance)
    // (x,y) is on the line
    // (x,y) isn't on the line
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