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Is there an easy way to determine if a point inside a triangle? It's 2D not 3D.

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Similar question for 3D – luser droog Dec 1 '15 at 0:05

15 Answers 15

up vote 130 down vote accepted

In general, the simplest (and quite optimal) algorithm is checking on which side of the half-plane created by the edges the point is.

Here's some high quality info in this topic on GameDev, including performance issues.

And here's some code to get you started:

float sign (fPoint p1, fPoint p2, fPoint p3)
    return (p1.x - p3.x) * (p2.y - p3.y) - (p2.x - p3.x) * (p1.y - p3.y);

bool PointInTriangle (fPoint pt, fPoint v1, fPoint v2, fPoint v3)
    bool b1, b2, b3;

    b1 = sign(pt, v1, v2) < 0.0f;
    b2 = sign(pt, v2, v3) < 0.0f;
    b3 = sign(pt, v3, v1) < 0.0f;

    return ((b1 == b2) && (b2 == b3));
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That's a pretty inefficient way of solving this problem, see my answer for a better approach. – Andreas Brinck Jan 12 '10 at 14:42
It's commonly used in 2D. Barycentric coordinates tend to confuse people. Also, given the cooridates of the triangle, and the point cordinate, I'm unsure about the efficiency of using barycentrics. – Kornel Kisielewicz Jan 12 '10 at 14:51
@Kornel The barycentric version is more efficient in 2D as well. Your solution also has the problem that it will report a different result for points exactly on the edges of the triangle depending on wether the triangle is specified in clockwise or counter clockwise order. – Andreas Brinck Jan 12 '10 at 15:09
For my purposes (the reason I found this site) the original answer proposed by Kornel Kisielewicz is much more efficient. I'm working with an LCD display with BYTE size coordinates and a very typical microprocessor where integer multiply is a very fast instruction, and division is much, much, slower. Numeric issues are also much smaller, due to no division! all calculations are exact. Thanks, Rick – user252020 Jan 16 '10 at 4:57
So the sign() function tells you which side of the halfplane (formed by the line between p2 and p3) p1 is? – David Doria Mar 25 '13 at 15:29

Solve the following equation system:

p = p0 + (p1 - p0) * s + (p2 - p0) * t

The point p is inside the triangle if 0 <= s <= 1 and 0 <= t <= 1 and s + t <= 1.

s,t and 1 - s - t are called the barycentric coordinates of the point p.

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@DR That's a little like saying you should use bubblesort instead of quicksort because recursion is hard to grasp ;) – Andreas Brinck Jan 12 '10 at 15:04
Those are not exactly the barycentric coordinates, just 2 of them. The 3rd is of course 1-s-t, and if all 3 are >= 0 the point is inside. – phkahler Jan 12 '10 at 18:50
With trivial exits (not implemented) in Kornel's method, his can actually far more efficient than yours. If you actually try to compute s and t you'll know what I mean. – Matthieu N. Jan 16 '10 at 22:14
I wanted to test this so I made a jsfiddle, relying on @andreasdr solution and coproc comment: – urraka Apr 9 '13 at 1:01
The article… proposed by @Logic post helped me to better understand this solution – Flayn Aug 25 '15 at 10:30

I agree with Andreas Brinck, barycentric coordinates are very convenient for this task. Note that there is no need to solve an equation system every time: just evaluate the analytical solution. Using Andreas' notation, the solution is:

s = 1/(2*Area)*(p0y*p2x - p0x*p2y + (p2y - p0y)*px + (p0x - p2x)*py);
t = 1/(2*Area)*(p0x*p1y - p0y*p1x + (p0y - p1y)*px + (p1x - p0x)*py);

where Area is the (signed) area of the triangle:

Area = 1/2*(-p1y*p2x + p0y*(-p1x + p2x) + p0x*(p1y - p2y) + p1x*p2y);

Just evaluate s, t and 1-s-t. The point p is inside the triangle if and only if they are all positive.

EDIT: Note that the above expression for the area assumes that the triangle node numbering is counter-clockwise. If the numbering is clockwise, this expression will return a negative area (but with correct magnitude). The test itself (s>0 && t>0 && 1-s-t>0) doesn't depend on the direction of the numbering, however, since the expressions above that are multiplied by 1/(2*Area) also change sign if the triangle node orientation changes.

EDIT 2: For an even better computational efficiency, see coproc's comment below (which makes the point that if the orientation of the triangle nodes (clockwise or counter-clockwise) is known beforehand, the division by 2*Area in the expressions for s and t can be avoided). See also Perro Azul's jsfiddle-code in the comments under Andreas Brinck's answer.

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That is solving the equation system :) – Andreas Brinck Jan 18 '13 at 15:36
Yes, my point is that any criticism of your method based on the computational cost of solving the equation system is unfounded, since that doesn't have to be done as part of the algorithm. – andreasdr Jan 19 '13 at 15:43
The efficiency can be improved by not dividing through 2*Area, i.e. by calculating s´=2*|Area|*s and t´=2*|Area|*t (if the orientation of the points - clockwise or counter-clockwise - is not known, the sign of Area has to be checked, of course, but otherwise it maybe does not even need to be computed), since for checking s>0 it suffices to check s´>0. And instead of checking 1-s-t>0 it suffices to check s´+t´<2*|Area|. – coproc Feb 4 '13 at 21:20
I may add that if p0->p1->p2 is counter-clockwise in Cartesian (which is usually clockwise in screen coordinates), the Area calculated by this method will be positive. – rhgb Jan 16 '14 at 16:42

I wrote this code before a final attempt with Google and finding this page, so I thought I'd share it. It is basically an optimized version of Kisielewicz answer. I looked into the Barycentric method also but judging from the Wikipedia article I have a hard time seeing how it is more efficient (I'm guessing there is some deeper equivalence). Anyway, this algorithm has the advantage of not using division; a potential problem is the behavior of the edge detection depending on orientation.

bool intpoint_inside_trigon(intPoint s, intPoint a, intPoint b, intPoint c)
    int as_x = s.x-a.x;
    int as_y = s.y-a.y;

    bool s_ab = (b.x-a.x)*as_y-(b.y-a.y)*as_x > 0;

    if((c.x-a.x)*as_y-(c.y-a.y)*as_x > 0 == s_ab) return false;

    if((c.x-b.x)*(s.y-b.y)-(c.y-b.y)*(s.x-b.x) > 0 != s_ab) return false;

    return true;

In words, the idea is this: Is the point s to the left of or to the right of both the lines AB and AC? If true, it can't be inside. If false, it is at least inside the "cones" that satisfy the condition. Now since we know that a point inside a trigon (triangle) must be to the same side of AB as BC (and also CA), we check if they differ. If they do, s can't possibly be inside, otherwise s must be inside.

Some keywords in the calculations are line half-planes and the determinant (2x2 cross product). Perhaps a more pedagogical way is probably to think of it as a point being inside iff it's to the same side (left or right) to each of the lines AB, BC and CA. The above way seemed a better fit for some optimization however.

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I wrote a complete article about point in triangle test. It shows the barycentric, parametric and dot product based methods.

Then it deals with the accuracy problem occuring when a point lies exactly on one edge (with examples). Finally it exposes a complete new method based on point to edge distance.

Enjoy !

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C# version of the barycentric method posted by andreasdr and Perro Azul. Note that the area calculation can be avoided if s and t have opposite signs. I verified correct behavior with a pretty thorough unit test.

public static bool PointInTriangle(Point p, Point p0, Point p1, Point p2)
    var s = p0.Y * p2.X - p0.X * p2.Y + (p2.Y - p0.Y) * p.X + (p0.X - p2.X) * p.Y;
    var t = p0.X * p1.Y - p0.Y * p1.X + (p0.Y - p1.Y) * p.X + (p1.X - p0.X) * p.Y;

    if ((s < 0) != (t < 0))
        return false;

    var A = -p1.Y * p2.X + p0.Y * (p2.X - p1.X) + p0.X * (p1.Y - p2.Y) + p1.X * p2.Y;
    if (A < 0.0)
        s = -s;
        t = -t;
        A = -A;
    return s > 0 && t > 0 && (s + t) <= A;

[edit: accepted suggested modification by @Pierre; see comments]

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The last line should read s > 0 && t > 0 && (s + t) <= A – Pierre Nov 24 '15 at 19:34

A simple way is to:

find the vectors connecting the point to each of the triangle's three vertices and sum the angles between those vectors. If the sum of the angles is 2*pi then the point is inside the triangle.

Two good sites that explain alternatives are:

blackpawn and wolfram

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Um, that method isn't exactly efficient, and is very prone to numerical errors... – Kornel Kisielewicz Jan 12 '10 at 14:35
It's quite the opposite, it's very inefficient :-) It's just one simple way though, that's easy to implement. Can you give an example of a numerical error this would cause? – Simon P Stevens Jan 12 '10 at 14:38

What I do is precalculate the three face normals,

  • in 3D by cross product of side vector and the face normal vector.

  • in 2D by simply swapping components and negating one,

then inside/outside for any one side is when a dot product of the side normal and the vertex to point vector, change sign. Repeat for other two (or more) sides.


  • a lot is precalculated so great for multiple point testing on same triangle.

  • early rejection of common case of more outside than inside points. (also if point distribution weighted to one side, can test that side first.)

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Here is an efficient Python implementation:

def PointInsideTriangle2(pt,tri):
    '''checks if point pt(2) is inside triangle tri(3x2). @Developer'''
    a = 1/(-tri[1,1]*tri[2,0]+tri[0,1]*(-tri[1,0]+tri[2,0])+ \
    s = a*(tri[2,0]*tri[0,1]-tri[0,0]*tri[2,1]+(tri[2,1]-tri[0,1])*pt[0]+ \
    if s<0: return False
    else: t = a*(tri[0,0]*tri[1,1]-tri[1,0]*tri[0,1]+(tri[0,1]-tri[1,1])*pt[0]+ \
    return ((t>0) and (1-s-t>0))

and an example output:

enter image description here

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Java version of barycentric method:

class Triangle {
    Triangle(double x1, double y1, double x2, double y2, double x3,
            double y3) {
        this.x3 = x3;
        this.y3 = y3;
        y23 = y2 - y3;
        x32 = x3 - x2;
        y31 = y3 - y1;
        x13 = x1 - x3;
        det = y23 * x13 - x32 * y31;
        minD = Math.min(det, 0);
        maxD = Math.max(det, 0);

    boolean contains(double x, double y) {
        double dx = x - x3;
        double dy = y - y3;
        double a = y23 * dx + x32 * dy;
        if (a < minD || a > maxD)
            return false;
        double b = y31 * dx + x13 * dy;
        if (b < minD || b > maxD)
            return false;
        double c = det - a - b;
        if (c < minD || c > maxD)
            return false;
        return true;

    private final double x3, y3;
    private final double y23, x32, y31, x13;
    private final double det, minD, maxD;

The above code will work accurately with integers, assuming no overflows. It will also work with clockwise and anticlockwise triangles. It will not work with collinear triangles (but you can check for that by testing det==0).

The barycentric version is fastest if you are going to test different points with the same triangle.

The barycentric version is not symmetric in the 3 triangle points, so it is likely to be less consistent than Kornel Kisielewicz's edge half-plane version, because of floating point rounding errors.

Credit: I made the above code from Wikipedia's article on barycentric coordinates.

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+1 Works flawlessly for me – user11153 Aug 24 '14 at 19:21

If you are looking for speed, here is a procedure that might help you.

Sort the triangle vertices on their ordinates. This takes at worst three comparisons. Let Y0, Y1, Y2 be the three sorted values. By drawing three horizontals through them you partition the plane into two half planes and two slabs. Let Y be the ordinate of the query point.

if Y < Y1
    if Y <= Y0 -> the point lies in the upper half plane, outside the triangle; you are done
    else Y > Y0 -> the point lies in the upper slab
    if Y >= Y2 -> the point lies in the lower half plane, outside the triangle; you are done
    else Y < Y2 -> the point lies in the lower slab

Costs two more comparisons. As you see, quick rejection is achieved for points outside of the "bounding slab".

Optionally, you can supply a test on the abscissas for quick rejection on the left and on the right (X <= X0' or X >= X2'). This will implement a quick bounding box test at the same time, but you'll need to sort on the abscissas too.

Eventually you will need to compute the sign of the given point with respect to the two sides of the triangle that delimit the relevant slab (upper or lower). The test has the form:

((X - Xi) * (Y - Yj) > (X - Xi) * (Y - Yj)) == ((X - Xi) * (Y - Yk) > (X - Xi) * (Y - Yk))

The complete discussion of i, j, k combinations (there are six of them, based on the outcome of the sort) is out of the scope of this answer and "left as an exercise to the reader"; for efficiency, they should be hard-coded.

If you think that this solution is complex, observe that it mainly involves simple comparisons (some of which can be precomputed), plus 6 subtractions and 4 multiplies in case the bounding box test fails. The latter cost is hard to beat as in the worst case you cannot avoid comparing the test point against two sides (no method in other answers has a lower cost, some make it worse, like 15 subtractions and 6 multiplies, sometimes divisions).

UPDATE: Faster with a shear transform

As explained just above, you can quickly locate the point inside one of the four horizontal bands delimited by the three vertex ordinates, using two comparisons.

You can optionally perform one or two extra X tests to check insideness to the bounding box (dotted lines).

Then consider the "shear" transform given by X'= X - m Y, Y' = Y, where m is the slope DX/DY for the highest edge. This transform will make this side of the triangle vertical. And since you know on what side of the middle horizontal you are, it suffices to test the sign with respect to a single side of the triangle.

enter image description here

Assuming you precomputed the slope m, as well as the X' for the sheared triangle vertices and the coefficients of the equations of the sides as X = m Y + p, you will need in the worst case

  • two ordinate comparisons for vertical classification;
  • optionally one or two abscissa comparisons for bounding box rejection;
  • computation of X' = X - m Y;
  • one or two comparisons with the abscissas of the sheared triangle;
  • one sign test X >< m' Y + p' against the relevant side of the sheared triangle.
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If you know the co-ordinates of the three vertices and the co-ordinates of the specific point, then you can get the area of the complete triangle. Afterwards, calculate the area of the three triangle segments (one point being the point given and the other two being any two vertices of the triangle). Thus, you will get the area of the three triangle segments. If the sum of these areas are equal to the total area (that you got previously), then, the point should be inside the triangle. Otherwise, the point is not inside the triangle. This should work. If there are any issues, let me know. Thank you.

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By using the analytic solution to the barycentric coordinates (pointed out by Andreas Brinck) and:

  • not distributing the multiplication over the parenthesized terms
  • avoiding computing several times the same terms by storing them
  • reducing comparisons (as pointed out by coproc and Thomas Eding)

one can minimize the number of "costy" operations:

function ptInTriangle(p, p0, p1, p2) {
    var dX = p.x-p2.x;
    var dY = p.y-p2.y;
    var dX21 = p2.x-p1.x;
    var dY12 = p1.y-p2.y;
    var D = dY12*(p0.x-p2.x) + dX21*(p0.y-p2.y);
    var s = dY12*dX + dX21*dY;
    var t = (p2.y-p0.y)*dX + (p0.x-p2.x)*dY;
    if (D<0) return s<=0 && t<=0 && s+t>=D;
    return s>=0 && t>=0 && s+t<=D;

(code can be pasted in Perro Azul jsfiddle)

Leading to:

  • variable "recalls": 30
  • variable storage: 7
  • additions: 4
  • substractions: 8
  • multiplications: 6
  • divisions: none
  • comparisons: 4

This compares quite well with Kornel Kisielewicz solution (25 recalls, 1 storage, 15 substractions, 6 multiplications, 5 comparisons), and might be even better if clockwise/counter-clockwise detection is needed (which takes 6 recalls, 1 addition, 2 substractions, 2 multiplications and 1 comparison in itself, using the analytic solution determinant, as pointed out by rhgb).

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There are pesky edge conditions where a point is exactly on the common edge of two adjacent triangles. The point cannot be in both, or neither of the triangles. You need an arbitrary but consistent way of assigning the point. For example, draw a horizontal line through the point. If the line intersects with the other side of the triangle on the right, the point is treated as though it is inside the triangle. If the intersection is on the left, the point is outside.

If the line on which the point lies is horizontal, use above/below.

If the point is on the common vertex of multiple triangles, use the triangle with whose center the point forms the smallest angle.

More fun: three points can be in a straight line (zero degrees), for example (0,0) - (0,10) - (0,5). In a triangulating algorithm, the "ear" (0,10) must be lopped off, the "triangle" generated being the degenerate case of a straight line.

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I needed point in triangle check in "controlable environment" when you're absolutely sure that triangles will be clockwise. So, I took Perro Azul's jsfiddle and modified it as suggested by coproc for such cases; also removed redundant 0.5 and 2 multiplications because they're just cancel each other.

Here is equivalent C# code for Unity:

public static bool IsPointInClockwiseTriangle(Vector2 p, Vector2 p0, Vector2 p1, Vector2 p2)
    var s = (p0.y * p2.x - p0.x * p2.y + (p2.y - p0.y) * p.x + (p0.x - p2.x) * p.y);
    var t = (p0.x * p1.y - p0.y * p1.x + (p0.y - p1.y) * p.x + (p1.x - p0.x) * p.y);

    if (s <= 0 || t <= 0)
        return false;

    var A = (-p1.y * p2.x + p0.y * (-p1.x + p2.x) + p0.x * (p1.y - p2.y) + p1.x * p2.y);

    return (s + t) < A;
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