I have drawn a line between two points A(x,y)B(x,y) Now I have a third point C(x,y). I want to know that if C lies on the line which is drawn between A and B. I want to do it in java language. I have found couple of answers similar to this. But, all have some problems and no one is perfect.
12 Answers
if (distance(A, C) + distance(B, C) == distance(A, B))
return true; // C is on the line.
return false; // C is not on the line.
or just:
return distance(A, C) + distance(B, C) == distance(A, B);
The way this works is rather simple. If C lies on the AB
line, you'll get the following scenario:
ACB
and, regardless of where it lies on that line, dist(AC) + dist(CB) == dist(AB)
. For any other case, you have a triangle of some description and 'dist(AC) + dist(CB) > dist(AB)':
AB
\ /
\ /
C
In fact, this even works if C lies on the extrapolated line:
CAB
provided that the distances are kept unsigned. The distance dist(AB)
can be calculated as:
___________________________
/ 2 2
V (A.x  B.x) + (A.y  B.y)
Keep in mind the inherent limitations (limited precision) of floating point operations. It's possible that you may need to opt for a "close enough" test (say, less than one part per million error) to ensure correct functioning of the equality.

1

This assumes the line is equidistant from A and B. i.e. it passes between the middle of A and B, not through it. Commented Jul 17, 2013 at 7:18

1This solution may be better for handling error. e.g. if the difference in distance is less than a pixel, C may appear on the line AB. Commented Jul 17, 2013 at 8:17

1@czifro There's something wrong with your calculations because
distance(C, A) = 3
,distance(C, B) = 10
anddistance(A, B) = 13
.– eshirimaCommented Nov 6, 2017 at 15:16 
2@DamianDixon That's not correct here, since you are adding the results of two square roots. (Sqrt(A) + Sqrt(B))^2 != (A + B). It's fine if you are comparing two distances directly, but not this way.– rgovCommented Jan 26, 2019 at 17:39
ATTENTION! Mathonly!
You can try this formula. Put your A(x1, y1)
and B(x2, y2)
coordinates to formula, then you'll get something like
y = k*x + b; // k and b  numbers
Then, any point which will satisfy this equation, will lie on your line.
To check that C(x, y)
is between A(x1, y1)
and B(x2, y2)
, check this: (x1<x<x2 && y1<y<y2)  (x1>x>x2 && y1>y>y2)
.
Example
A(2,3) B(6,5)
The equation of line:
(y  3)/(5  3) = (x  2)/(6  2)
(y  3)/2 = (x  2)/4
4*(y  3) = 2*(x  2)
4y  12 = 2x  4
4y = 2x + 8
y = 1/2 * x + 2; // equation of line. k = 1/2, b = 2;
Let's check if C(4,4)
lies on this line.
2<4<6 & 3<4<5 // C between A and B
Now put C coordinates to equation:
4 = 1/2 * 4 + 2
4 = 2 + 2 // equal, C is on line AB
PS: as @paxdiablo wrote, you need to check if line is horizontal or vertical before calculating. Just check
y1 == y2  x1 == x2

what is the purpose of y = k*x + b; // k and b  numbers what is the value of k and b ? Commented Jul 17, 2013 at 7:12


9Don't try this at home if your lines can be horizontal or vertical :) Commented Jul 17, 2013 at 7:20

1I believe if you do
(x1  x2)(y  y1) == (y1  y2)(x  x1)
, you do not need to do a horizontal or vertical check prior. Obviously the checks are to avoid divide by zero, but this does not suffer from that.– czifroCommented Apr 25, 2016 at 3:05 
1However, bounds checking is necessary for horizontal and vertical lines.– czifroCommented Apr 25, 2016 at 3:11
If you just want to check whether the point C is on the infinite line passing through the points A and B (rather than check whether C is on the line segment from A to B, i.e. C is also between them), the simplest implementation is:
// Are a, b and c on the same line?
public static boolean inLine(Point a, Point b, Point c) {
return (a.x  c.x)*(c.y  b.y) == (c.x  b.x)*(a.y  c.y);
}
This is morally equivalent to checking that gradient(A, C) == gradient(C, B), but rearranged to use multiplication instead of division to avoid dividebyzero when one of the gradients is vertical (also, it gives exact results if using integers).
It is equivalent to checking that the cross product of (A  C) and (C  B) is equal to 0. The property of three points being on the same line is known as collinearity.
Note: there is a different test to see if C appears on the line between A and B if you draw it on a screen. Maths assumes that A, B, C are infinitely small points.

This has the same problem as SeniorJD's answer. The gradient for a vertical line is infinite (or, more correctly, undefined but tends towards infinity). Commented Jul 17, 2013 at 7:25

@paxdiablo Not dividing by 0 any more but I am not this solves the whole problem. Commented Jul 17, 2013 at 8:21

5For vertical lines or horizontal lines, this test (by itself) will return true if the point has the same x value for vertical lines, or y value for horizontal lines, regardless of whether or not the point is in between the end points of the line.– ShavaisCommented Jan 19, 2015 at 6:23

how would this work for horizontal lines on say the x axis Commented May 12, 2018 at 3:26

2Have to check that C.x in A.x..B.x and C.y in A.y..B.y. Otherwise you will match collinear points which are not between A and B Commented Dec 10, 2019 at 18:18
The above answers are unnecessarily complicated. The simplest is as follows.
if (xx1)/(x2x1) = (yy1)/(y2y1) = alpha (a constant), then the point C(x,y) will lie on the line between pts 1 & 2.
If alpha < 0.0, then C is exterior to point 1.
 If alpha > 1.0, then C is exterior to point 2.
 Finally if alpha = [0,1.0], then C is interior to 1 & 2.
Hope this answer helps.

1

In this context, exterior means the point lies on the infinite line that passes point 1 and 2, but not on the line segment between the same two points. Commented May 22, 2023 at 6:11

It deosn't make sense in math nor does it in programming. I guess there is a typo. the first "=" should be minus or something like that– AznavehCommented Sep 12, 2023 at 16:27
I think all the methods here have a pitfall, in that they are not dealing with rounding errors as rigorously as they could. Basically the methods described will tell you if your point is close enough to the line using some straightforward algorithm and that it will be more or less precise.
Why precision is important? Because it's the very problem presented by op. For a computer program there is no such thing as a point on a line, there is only point within an epsilon of a line and what that epsilon is needs to be documented.
Let's illustrate the problem. Using the distance comparison algorithm:
Let's say a segment goes from (0, 0) to (0, 2000), we are using floats in our application (which have around 7 decimal places of precision) and we test whether a point on (1E6, 1000) is on the line or not.
The distance from either end of the segment to the point is 1000.0000000005 or 1000 + 5E10, and, thus, the difference with the addition of the distance to and from the point is around 1E9. But none of those values can be stored on a float with enough precission and the method will return true
.
If we use a more precise method like calculating the distance to the closest point in the line, it returns a value that a float has enough precision to store and we could return false depending on the acceptable epsilon.
I used floats in the example but the same applies to any floating point type such as double.
One solution is to use BigDecimal and whichever method you want if incurring in performance and memory hit is not an issue.
A more precise method than comparing distances for floating points, and, more importantly, consistently precise, although at a higher computational cost, is calculating the distance to the closest point in the line.
Shortest distance between a point and a line segment
It looks like I'm splitting hairs but I had to deal with this problem before. It's an issue when chaining geometric operations. If you don't control what kind of precission loss you are dealing with, eventually you will run into difficult bugs that will force you to reason rigorously about the code in order to fix them.
An easy way to do that I believe would be the check the angle formed by the 3 points. If the angle ACB is 180 degrees (or close to it,depending on how accurate you want to be) then the point C is between A and B.
I think this might help
How to check if a point lies on a line between 2 other points
That solution uses only integers given you only provide integers which removes some pitfalls as well
Here is my C# solution. I believe the Java equivalent will be almost identical.
Notes:
Method will only return true if the point is within the bounds of the line (it does not assume an infinite line).
It will handle vertical or horizontal lines.
It calculates the distance of the point being checked from the line so allows a tolerance to be passed to the method.
/// <summary> /// Check if Point C is on the line AB /// </summary> public static bool IsOnLine(Point A, Point B, Point C, double tolerance) { double minX = Math.Min(A.X, B.X)  tolerance; double maxX = Math.Max(A.X, B.X) + tolerance; double minY = Math.Min(A.Y, B.Y)  tolerance; double maxY = Math.Max(A.Y, B.Y) + tolerance; //Check C is within the bounds of the line if (C.X >= maxX  C.X <= minX  C.Y <= minY  C.Y >= maxY) { return false; } // Check for when AB is vertical if (A.X == B.X) { if (Math.Abs(A.X  C.X) >= tolerance) { return false; } return true; } // Check for when AB is horizontal if (A.Y == B.Y) { if (Math.Abs(A.Y  C.Y) >= tolerance) { return false; } return true; } // Check istance of the point form the line double distFromLine = Math.Abs(((B.X  A.X)*(A.Y  C.Y))((A.X  C.X)*(B.Y  A.Y))) / Math.Sqrt((B.X  A.X) * (B.X  A.X) + (B.Y  A.Y) * (B.Y  A.Y)); if (distFromLine >= tolerance) { return false; } else { return true; } }
if ( (ymid  y1) * (x2x1) == (xmid  x1) * (y2y1) ) **is true, Z lies on line AB**
Start Point : A (x1, y1),
End Point : B (x2, y2),
Point That is on Line AB or Not : Z (xmid, ymid)
I just condensed everyone's answers and this formula works the best for me.
 It avoids division by zero
 No distance calculation required
 Simple to implement
Edit: In case you are dealing with floats, which you most probably are, use this:
if( (ymid  y1) * (x2x1)  (xmid  x1) * (y2y1) < DELTA )
where the tolerance DELTA is a value close to zero. I usually set it to 0.05
def DistBetwPoints(p1, p2):
return math.sqrt( (p2[0]  p1[0])**2 + (p2[1]  p1[1])**2 )
# "Check if point C is between line endpoints A and B"
def PointBetwPoints(A, B, C):
dist_line_endp = DistBetwPoints(A,B)
if DistBetwPoints(A,C)>dist_line_endp: return 1
elif DistBetwPoints(B,C)>dist_line_endp: return 1
else: return 0
Here is a JavaScript function I made. You pass it three points (three objects with an x and y property). Points 1 and 2 define your line, and point 3 is the point you are testing.
You will receive an object back with some useful info:
on_projected_line
 Ifpt3
lies anywhere on the line including outside the points.on_line
 Ifpt3
lies on the line and between or onpt1
andpt2
.x_between
 Ifpt3
is between or on the x bounds.y_between
 Ifpt3
is between or on the y bounds.between
 Ifx_between
andy_between
are both true.
/**
* @description Check if pt3 is on line defined by pt1 and pt2.
* @param {Object} pt1 The first point defining the line.
* @param {float} pt1.x
* @param {float} pt1.y
* @param {Object} pt2 The second point defining the line.
* @param {float} pt2.x
* @param {float} pt2.y
* @param {Object} pt3 The point to test.
* @param {float} pt3.x
* @param {float} pt3.y
*/
function pointOnLine(pt1, pt2, pt3) {
const result = {
on_projected_line: true,
on_line: false,
between_both: false,
between_x: false,
between_y: false,
};
// Determine if on line interior or exterior
const x = (pt3.x  pt1.x) / (pt2.x  pt1.x);
const y = (pt3.y  pt1.y) / (pt2.y  pt1.y);
// Check if on line equation
result.on_projected_line = x === y;
// Check within x bounds
if (
(pt1.x <= pt3.x && pt3.x <= pt2.x) 
(pt2.x <= pt3.x && pt3.x <= pt1.x)
) {
result.between_x = true;
}
// Check within y bounds
if (
(pt1.y <= pt3.y && pt3.y <= pt2.y) 
(pt2.y <= pt3.y && pt3.y <= pt1.y)
) {
result.between_y = true;
}
result.between_both = result.between_x && result.between_y;
result.on_line = result.on_projected_line && result.between_both;
return result;
}
console.log("pointOnLine({x: 0, y: 0}, {x: 1, y: 1}, {x: 2, y: 2})")
console.log(pointOnLine({x: 0, y: 0}, {x: 1, y: 1}, {x: 2, y: 2}))
console.log("pointOnLine({x: 0, y: 0}, {x: 1, y: 1}, {x: 0.5, y: 0.5})")
console.log(pointOnLine({x: 0, y: 0}, {x: 1, y: 1}, {x: 0.5, y: 0.5}))
One good library is available for this by turfjs.
var pt = turf.point([0, 0]);
var line = turf.lineString([[1, 1],[1, 1],[1.5, 2.2]]);
var isPointOnLine = turf.booleanPointOnLine(pt, line);
If you want to reduce the accuracy use epsilon
option
turf.booleanPointOnLine([c1, c2], turf.lineString([[x1, y1], [x2, y2]]), {epsilon: 10}))
Hope this is helpful
Line2D
object that represents A & B and use it'scontains
method