# Find if point lays on line segment

I have line segment defined by two points A(x1,y1,z1) and B(x2,y2,z2) and point p(x,y,z). How can I check if the point lays on the line segment?

• Why is this tagged C#? – Karl Knechtel - away from home Aug 13 '11 at 14:09
• because I need any sample code in c# – AMH Aug 13 '11 at 14:15
• yeah, it sounded obvious to me :) – Leggy7 Jan 2 '14 at 9:11
• I tried to reply to MetaMapper's post but I don't have a 50 reputation. MetaMapper's solution is wrong. I personally spent a lot of time debugging and I wouldn't want anyone else to have to go through the same thing. Andy's solution is correct. It just has to be converted to C#. I hope this saves someone some time. – Ruell Black Jul 3 '18 at 22:24

## 11 Answers

If the point is on the line then:

``````(x - x1) / (x2 - x1) = (y - y1) / (y2 - y1) = (z - z1) / (z2 - z1)
``````

Calculate all three values, and if they are the same (to some degree of tolerance), your point is on the line.

To test if the point is in the segment, not just on the line, you can check that

``````x1 < x < x2, assuming x1 < x2, or
y1 < y < y2, assuming y1 < y2, or
z1 < z < z2, assuming z1 < z2
``````
• x,y,z is the point I want t check if lay on or not true ?! – AMH Aug 13 '11 at 13:58
• One of them is the point you're checking, and the other two are the endpoints of the line. It doesn't matter which name you give to each point, as long as you are consistent. – Karl Knechtel - away from home Aug 13 '11 at 14:08
• Your test will fail if x1 == x2 or y1 == y2 – Jeriho Jan 29 '13 at 15:55
• just to complete this answer, here you can find the complete mathematical explaination – Leggy7 Jan 2 '14 at 10:14
• And fails if x is close to x1 or y is close to y1 or z is close to z1 due to unfixable floating point precision problems. Don't use this solution. Fine for a math exam, but completely wrong answer for c# code. – Robin Davies Apr 5 '17 at 4:04

Find the distance of point P from both the line end points A, B. If AB = AP + PB, then P lies on the line segment AB.

``````AB = sqrt((x2-x1)*(x2-x1)+(y2-y1)*(y2-y1)+(z2-z1)*(z2-z1));
AP = sqrt((x-x1)*(x-x1)+(y-y1)*(y-y1)+(z-z1)*(z-z1));
PB = sqrt((x2-x)*(x2-x)+(y2-y)*(y2-y)+(z2-z)*(z2-z));
if(AB == AP + PB)
return true;
``````
• I know this is pretty late, but this answer works a lot better than the accepted answer. Especially since it works when a point is on the line segment start or end. – Roy T. Jul 28 '14 at 13:08
• Excellent answer. One thing you might want to consider is floating point rounding errors. Let's say AB = 12.0000001 and AP + PB = 12.000003, you still might want to consider things being "close enough", depending on what you are doing. – Joel B Mar 26 '15 at 15:19
• How about its speed? Sqrt's are pretty slow, compared to division. – Sushi271 Aug 19 '16 at 11:41
• Not at all, processors have a dedicated instruction for Math.Sqrt(). It takes just as long as a division. – Hans Passant Jun 9 at 10:41

First take the cross product of AB and AP. If they are colinear, then it will be 0.

At this point, it could still be on the greater line extending past B or before A, so then I think you should be able to just check if pz is between az and bz.

This appears to be a duplicate, actually, and as one of the answers mentions, it is in Beautiful Code.

Your segment is best defined by parametric equation

for all points on your segment, following equation holds: x = x1 + (x2 - x1) * p y = y1 + (y2 - y1) * p z = z1 + (z2 - z1) * p

Where p is a number in [0;1]

So, if there is a p such that your point coordinates satisfy those 3 equations, your point is on this line. And it p is between 0 and 1 - it is also on line segment

• you mean I use p for example equal 1 and check – AMH Aug 13 '11 at 12:50
• No, you just solve 3 equations against p - if all 3 values are equal within reasonable error (it's floating point - no exact match will be there), then your point is on that straight line. If p is between 0 and 1, then it is inside segment – Konstantin Pribluda Aug 13 '11 at 13:23
• @KonstantinPribluda - thanks for the explanation. I added an answer based on your answer. – Andy Apr 29 '13 at 6:00

in case if someone looks for inline version:

``````public static bool PointOnLine2D (this Vector2 p, Vector2 a, Vector2 b, float t = 1E-03f)
{
// ensure points are collinear
var zero = (b.x - a.x) * (p.y - a.y) - (p.x - a.x) * (b.y - a.y);
if (zero > t || zero < -t) return false;

// check if x-coordinates are not equal
if (a.x - b.x > t || b.x - a.x > t)
// ensure x is between a.x & b.x (use tolerance)
return a.x > b.x
? p.x + t > b.x && p.x - t < a.x
: p.x + t > a.x && p.x - t < b.x;

// ensure y is between a.y & b.y (use tolerance)
return a.y > b.y
? p.y + t > b.y && p.y - t < a.y
: p.y + t > a.y && p.y - t < b.y;
}
``````
• Excluding your epsilon (ie. t) zero check, the colinear check can be written as if (Vector.crossProduct(u = new Vector(a, b), new Vector(u, new Vector(a, p))) != 0) return false; – Borgboy Sep 18 '16 at 23:15

Here's some C# code for the 2D case:

``````public static bool PointOnLineSegment(PointD pt1, PointD pt2, PointD pt, double epsilon = 0.001)
{
if (pt.X - Math.Max(pt1.X, pt2.X) > epsilon ||
Math.Min(pt1.X, pt2.X) - pt.X > epsilon ||
pt.Y - Math.Max(pt1.Y, pt2.Y) > epsilon ||
Math.Min(pt1.Y, pt2.Y) - pt.Y > epsilon)
return false;

if (Math.Abs(pt2.X - pt1.X) < epsilon)
return Math.Abs(pt1.X - pt.X) < epsilon || Math.Abs(pt2.X - pt.X) < epsilon;
if (Math.Abs(pt2.Y - pt1.Y) < epsilon)
return Math.Abs(pt1.Y - pt.Y) < epsilon || Math.Abs(pt2.Y - pt.Y) < epsilon;

double x = pt1.X + (pt.Y - pt1.Y) * (pt2.X - pt1.X) / (pt2.Y - pt1.Y);
double y = pt1.Y + (pt.X - pt1.X) * (pt2.Y - pt1.Y) / (pt2.X - pt1.X);

return Math.Abs(pt.X - x) < epsilon || Math.Abs(pt.Y - y) < epsilon;
}
``````

The cross product (B - A) × (p - A) should be much much shorter than B - A. Ideally, the cross product is zero, but that's unlikely on finite-precision floating-point hardware.

Based on Konstantin's answer above, here is some C code to find if a point is actually on a FINITE line segment. This takes into account horizontal/vertical line segments. This also takes in to account that floating point numbers are never really "exact" when comparing them with one another. The default epsilon of 0.001f will suffice in most cases. This is for 2D lines... adding "Z" would be trivial. PointF class is from GDI+, which is basically just: `struct PointF{float X,Y};`

Hope this helps!

``````#define DEFFLEQEPSILON 0.001
#define FLOAT_EQE(x,v,e)((((v)-(e))<(x))&&((x)<((v)+(e))))

static bool Within(float fl, float flLow, float flHi, float flEp=DEFFLEQEPSILON){
if((fl>flLow) && (fl<flHi)){ return true; }
if(FLOAT_EQE(fl,flLow,flEp) || FLOAT_EQE(fl,flHi,flEp)){ return true; }
return false;
}

static bool PointOnLine(const PointF& ptL1, const PointF& ptL2, const PointF& ptTest, float flEp=DEFFLEQEPSILON){
bool bTestX = true;
const float flX = ptL2.X-ptL1.X;
if(FLOAT_EQE(flX,0.0f,flEp)){
// vertical line -- ptTest.X must equal ptL1.X to continue
if(!FLOAT_EQE(ptTest.X,ptL1.X,flEp)){ return false; }
bTestX = false;
}
bool bTestY = true;
const float flY = ptL2.Y-ptL1.Y;
if(FLOAT_EQE(flY,0.0f,flEp)){
// horizontal line -- ptTest.Y must equal ptL1.Y to continue
if(!FLOAT_EQE(ptTest.Y,ptL1.Y,flEp)){ return false; }
bTestY = false;
}
// found here: http://stackoverflow.com/a/7050309
// x = x1 + (x2 - x1) * p
// y = y1 + (y2 - y1) * p
// solve for p:
const float pX = bTestX?((ptTest.X-ptL1.X)/flX):0.5f;
const float pY = bTestY?((ptTest.Y-ptL1.Y)/flY):0.5f;
return Within(pX,0.0f,1.0f,flEp) && Within(pY,0.0f,1.0f,flEp);
}
``````
• This is not C# code at all. You may want to find more appropriate question for this answer - C is not in any way related to C#. – Alexei Levenkov Mar 17 '17 at 22:58
• @AlexeiLevenkov -- If you can't convert basic C++ to C#, then maybe you need to rethink what you're doing in life. – Andy Mar 19 '17 at 2:14
• I'm very happy that all people you know on SO can easily read C# and C equally well - unfortunately I have less confidence that it is the case (note that making such a generic assumption about all people who can't read C code with macros may be considered not polite by some). Feel free to bring up this to Meta (in the past it was against posting answers in wrong language meta.stackoverflow.com/questions/290046/… , so make sure to clearly explain your reasoning if decided to bring it up). – Alexei Levenkov Mar 19 '17 at 3:03

I use this to calculate the distance AB between points a and b.

``````static void Main(string[] args)
{
double AB = segment(0, 1, 0, 4);
Console.WriteLine("Length of segment AB: {0}",AB);
}

static double segment (int ax,int ay, int bx, int by)
{
Vector a = new Vector(ax,ay);
Vector b = new Vector(bx,by);
Vector c = (a & b);
return Math.Sqrt(c.X + c.Y);
}

struct Vector
{
public readonly float X;
public readonly float Y;

public Vector(float x, float y)
{
this.X = x;
this.Y = y;
}
public static Vector operator &(Vector a, Vector b)
{
return new Vector((b.X - a.X) * (b.X - a.X), (b.Y - a.Y) * (b.Y - a.Y));
}
}
``````

Let V1 be the vector (B-A), and V2 = (p-A), normalize both V1 and V2.

If V1==(-V2) then the point p is on the line, but preceding A, & therefore not in the segment. If V1==V2 the point p is on the line. Get the length of (p-A) and check if this is less-or-equal to length of (B-A), if so the point is on the segment, else it is past B.

You could check if the point lies between the two planes defined by point1 and point2 and the line direction:

``````///  Returns the closest point from @a point to this line on this line.
vector3 <Type>
line3d <Type>::closest_point (const vector3 <Type> & point) const
{
return this -> point () + direction () * dot (point - this -> point (), direction ());
}

///  Returns true if @a point lies between point1 and point2.
template <class Type>
bool
line_segment3 <Type>::is_between (const vector3 <Type> & point) const
{
const auto closest = line () .closest_point (point);
return abs ((closest - point0 ()) + (closest - point1 ())) <= abs (point0 () - point1 ());
}
``````
• This is not C# code at all - so not useful for this question - could be fine for C/C++ version of the same Q... And explanation is not very friendly for average person. – Alexei Levenkov Mar 17 '17 at 22:56