# Shortest distance between a point and a line segment

I need a basic function to find the shortest distance between a point and a line segment. Feel free to write the solution in any language you want; I can translate it into what I'm using (Javascript).

EDIT: My line segment is defined by two endpoints. So my line segment `AB` is defined by the two points `A (x1,y1)` and `B (x2,y2)`. I'm trying to find the distance between this line segment and a point `C (x3,y3)`. My geometry skills are rusty, so the examples I've seen are confusing, I'm sorry to admit.

``````%Matlab solution by Tim from Cody
function ans=distP2S(x0,y0,x1,y1,x2,y2)
% Point is x0,y0
z=complex(x0-x1,y0-y1);
complex(x2-x1,y2-y1);
abs(z-ans*min(1,max(0,real(z/ans))));
``````

the accepted answer does not work (e.g. distance between 0,0 and (-10,2,10,2) should be 2).

here's code that works:

``````   def dist2line2(x,y,line):
x1,y1,x2,y2=line
vx = x1 - x
vy = y1 - y
ux = x2-x1
uy = y2-y1
length = ux * ux + uy * uy
det = (-vx * ux) + (-vy * uy) #//if this is < 0 or > length then its outside the line segment
if det < 0:
return (x1 - x)**2 + (y1 - y)**2
if det > length:
return (x2 - x)**2 + (y2 - y)**2
det = ux * vy - uy * vx
return det**2 / length
def dist2line(x,y,line): return math.sqrt(dist2line2(x,y,line))
``````

A little cleaner solution in JavaScript based on this formula:

``````distToSegment: function (point, linePointA, linePointB){

var x0 = point.X;
var y0 = point.Y;

var x1 = linePointA.X;
var y1 = linePointA.Y;

var x2 = linePointB.X;
var y2 = linePointB.Y;

var Dx = (x2 - x1);
var Dy = (y2 - y1);

var numerator = Math.abs(Dy*x0 - Dx*y0 - x1*y2 + x2*y1);
var denominator = Math.sqrt(Dx*Dx + Dy*Dy);
if (denominator == 0) {
return this.dist2(point, linePointA);
}

return numerator/denominator;

}
``````
• Kudos for actually writing a formula down. However, this is the formula to calculate the distance to a line, not to a line segment. Picking (x0,y0)=(-10,0), (x1,y1)=(0,0), and (x2,y2)=(10,0) gives a distance of 0, while it should have been 10. – Anne van Rossum Oct 7 '14 at 7:56

This algorithm is based on finding the intersection between the specified line and the orthogonal line, which contains the specified point, and calculating its distance. In case of a line segment, we must check if the intersection is between points of the line segment, if that's not the case then the minimum distance is between the specified point and one of the ending points of the line segment. This is a C# implementation.

``````Double Distance(Point a, Point b)
{
double xdiff = a.X - b.X, ydiff = a.Y - b.Y;
return Math.Sqrt((long)xdiff * xdiff + (long)ydiff * ydiff);
}

Boolean IsBetween(double x, double a, double b)
{
return ((a <= b && x >= a && x <= b) || (a > b && x <= a && x >= b));
}

Double GetDistance(Point pt, Point pt1, Point pt2, out Point intersection)
{
Double a, x, y, R;

if (pt1.X != pt2.X) {
a = (double)(pt2.Y - pt1.Y) / (pt2.X - pt1.X);
x = (a * (pt.Y - pt1.Y) + a * a * pt1.X + pt.X) / (a * a + 1);
y = a * x + pt1.Y - a * pt1.X; }
else { x = pt1.X;  y = pt.Y; }

if (IsBetween(x, pt1.X, pt2.X) && IsBetween(y, pt1.Y, pt2.Y)) {
intersection = new Point((int)x, (int)y);
R = Distance(intersection, pt); }
else {
double d1 = Distance(pt, pt1), d2 = Distance(pt, pt2);
if (d1 < d2) { intersection = pt1; R = d1; }
else { intersection = pt2; R = d2; }}

return R;
}
``````
• Thank you! Needed to find the intersection in Java, and this translated perfectly! – maharvey67 May 20 '18 at 9:51

I've made an interactive Desmos graph to demonstrate how to achieve this:

https://www.desmos.com/calculator/kswrm8ddum

The red point is A, the green point is B, and the point C is blue. You can drag the points in the graph to see the values change. On the left, the value 's' is the parameter of the line segment (i.e. s = 0 means the point A, and s = 1 means the point B). The value 'd' is the distance from the third point to the line through A and B.

EDIT:

Fun little insight: the coordinate (s, d) is the coordinate of the third point C in the coordinate system where AB is the unit x-axis, and the unit y-axis is perpendicular to AB.

Here is one based on vector math; this solution will also work for higher dimensions and also report on the interection point (on the line segment).

``````def dist(x1,y1,x2,y2,px,py):
a = np.array([[x1,y1]]).T
b = np.array([[x2,y2]]).T
x = np.array([[px,py]]).T
tp = (np.dot(x.T, b) - np.dot(a.T, b)) / np.dot(b.T, b)
tp = tp[0][0]
tmp = x - (a + tp*b)
d = np.sqrt(np.dot(tmp.T,tmp)[0][0])
return d, a+tp*b

x1,y1=2.,2.
x2,y2=5.,5.
px,py=4.,1.

d, inters = dist(x1,y1, x2,y2, px,py)
print (d)
print (inters)
``````

Result is

``````2.1213203435596424
[[2.5]
[2.5]]
``````

The math is explained here

https://brilliant.org/wiki/distance-between-point-and-line/

Python Numpy implementation for 2D coordinate array:

``````import numpy as np

def dist2d(p1, p2, coords):
''' Distance from points to a finite line btwn p1 -> p2 '''
assert coords.ndim == 2 and coords.shape[1] == 2, 'coords is not 2 dim'
dp = p2 - p1
st = dp[0]**2 + dp[1]**2
u = ((coords[:, 0] - p1[0]) * dp[0] + (coords[:, 1] - p1[1]) * dp[1]) / st

u[u > 1.] = 1.
u[u < 0.] = 0.

dx = (p1[0] + u * dp[0]) - coords[:, 0]
dy = (p1[1] + u * dp[1]) - coords[:, 1]

return np.sqrt(dx**2 + dy**2)

# Usage:
p1 = np.array([0., 0.])
p2 = np.array([0., 10.])

# List of coordinates
coords = np.array(
[[0., 0.],
[5., 5.],
[10., 10.],
[20., 20.]
])

d = dist2d(p1, p2, coords)

# Single coordinate
coord = np.array([25., 25.])
d = dist2d(p1, p2, coord[np.newaxis, :])
``````

Matlab direct Grumdrig implementation

``````function ans=distP2S(px,py,vx,vy,wx,wy)
% [px py vx vy wx wy]
t=( (px-vx)*(wx-vx)+(py-vy)*(wy-vy) )/idist(vx,wx,vy,wy)^2;
[idist(px,vx,py,vy) idist(px,vx+t*(wx-vx),py,vy+t*(wy-vy)) idist(px,wx,py,wy) ];
ans(1+(t>0)+(t>1)); % <0 0<=t<=1 t>1
end

function d=idist(a,b,c,d)
d=abs(a-b+1i*(c-d));
end
``````

If its an infinite line, not a line segment, the simplest way is this (in ruby), where mx + b is the line and (x1, y1) is the known point

``````(y1 - mx1 - b).abs / Math.sqrt(m**2 + 1)
``````
• You haven't defined `mx1`, `b` or `m` and your solution is not for line segments. – Jon Harrop Sep 29 '13 at 16:09

Just came across this and thought I'd add a Lua implementation. It assumes that points are given as tables {x=xVal, y=yVal} and the line or segment is given by a table containing two points (see example below):

``````function distance( P1, P2 )
return math.sqrt((P1.x-P2.x)^2 + (P1.y-P2.y)^2)
end

-- Returns false if the point lies beyond the reaches of the segment
function distPointToSegment( line, P )
if line[1].x == line[2].x and line[1].y == line[2].y then
print("Error: Not a line!")
return false
end

local d = distance( line[1], line[2] )

local t = ((P.x - line[1].x)*(line[2].x - line[1].x) + (P.y - line[1].y)*(line[2].y - line[1].y))/(d^2)

local projection = {}
projection.x = line[1].x + t*(line[2].x-line[1].x)
projection.y = line[1].y + t*(line[2].y-line[1].y)

if t >= 0 and t <= 1 then   -- within line segment?
return distance( projection, {x=P.x, y=P.y} )
else
return false
end
end

-- Returns value even if point is further down the line (outside segment)
function distPointToLine( line, P )
if line[1].x == line[2].x and line[1].y == line[2].y then
print("Error: Not a line!")
return false
end

local d = distance( line[1], line[2] )

local t = ((P.x - line[1].x)*(line[2].x - line[1].x) + (P.y - line[1].y)*(line[2].y - line[1].y))/(d^2)

local projection = {}
projection.x = line[1].x + t*(line[2].x-line[1].x)
projection.y = line[1].y + t*(line[2].y-line[1].y)

return distance( projection, {x=P.x, y=P.y} )
end
``````

Example usage:

``````local P1 = {x = 0, y = 0}
local P2 = {x = 10, y = 10}
local line = { P1, P2 }
local P3 = {x = 7, y = 15}
print(distPointToLine( line, P3 ))  -- prints 5.6568542494924
print(distPointToSegment( line, P3 )) -- prints false
``````

Wanted to do this in GLSL, but it's better to avoid all those conditionals if possible. Using clamp() avoids the two end-point cases:

``````// find closest point to P on line segment AB:
vec3 closest_point_on_line_segment(in vec3 P, in vec3 A, in vec3 B) {
vec3 AP = P - A, AB = B - A;
float l = dot(AB, AB);
if (l <= 0.0000001) return A;    // A and B are practically the same
return AP - AB*clamp(dot(AP, AB)/l, 0.0, 1.0);  // do the projection
}
``````

If you can be sure that A and B are never very close to each other, this can be simplified to remove the if(). In fact, even if A and B are the same, my GPU still gives the right result with this condition-free version (but this is using pre-OpenGL 4.1 in which GLSL divide by zero is undefined):

``````// find closest point to P on line segment AB:
vec3 closest_point_on_line_segment(in vec3 P, in vec3 A, in vec3 B) {
vec3 AP = P - A, AB = B - A;
return AP - AB*clamp(dot(AP, AB)/dot(AB, AB), 0.0, 1.0);
}
``````

To compute the distance is trivial -- GLSL provides a distance() function which you can use on this closest point and P.

Same as this answer, except in Visual Basic. Makes it usable as a User Defined Function in Microsoft Excel and VBA/macros.

The function returns the closest distance from point (x,y) to the segment defined by (x1,y1) and (x2,y2)

``````Function DistanceToSegment(x As Double, y As Double, x1 As Double, y1 As Double, x2 As Double, y2 As Double)

Dim A As Double
A = x - x1
Dim B As Double
B = y - y1
Dim C  As Double
C = x2 - x1
Dim D As Double
D = y2 - y1

Dim dot As Double
dot = A * C + B * D
Dim len_sq As Double
len_sq = C * C + D * D
Dim param As Double
param = -1

If (len_sq <> 0) Then
param = dot / len_sq
End If

Dim xx As Double
Dim yy As Double

If (param < 0) Then
xx = x1
yy = y1
ElseIf (param > 1) Then
xx = x2
yy = y2
Else
xx = x1 + param * C
yy = y1 + param * D
End If

Dim dx As Double
dx = x - xx
Dim dy As Double
dy = y - yy

DistanceToSegment = Math.Sqr(dx * dx + dy * dy)

End Function
``````

Lua: Finds minimum distance between a line segment(not the whole line) and a point

``````function solveLinearEquation(A1,B1,C1,A2,B2,C2)
--it is the implitaion of a method of solving linear equations in x and y
local f1 = B1*C2 -B2*C1
local f2 = A2*C1-A1*C2
local f3 = A1*B2 -A2*B1
return {x= f1/f3, y= f2/f3}
end

function pointLiesOnLine(x,y,x1,y1,x2,y2)
local dx1 = x-x1
local  dy1 = y-y1
local dx2 = x-x2
local  dy2 = y-y2
local crossProduct = dy1*dx2 -dx1*dy2

if crossProduct ~= 0  then  return  false
else
if ((x1>=x) and (x>=x2)) or ((x2>=x) and (x>=x1)) then
if ((y1>=y) and (y>=y2)) or ((y2>=y) and (y>=y1)) then
return true
else return false end
else  return false end
end
end

function dist(x1,y1,x2,y2)
local dx = x1-x2
local dy = y1-y2
return math.sqrt(dx*dx + dy* dy)
end

function findMinDistBetnPointAndLine(x1,y1,x2,y2,x3,y3)
-- finds the min  distance between (x3,y3) and line (x1,y2)--(x2,y2)
local A2,B2,C2,A1,B1,C1
local dx = y2-y1
local dy = x2-x1
if dx == 0 then A2=1 B2=0 C2=-x3 A1=0 B1=1 C1=-y1
elseif dy == 0 then A2=0 B2=1 C2=-y3 A1=1 B1=0 C1=-x1
else
local m1 = dy/dx
local m2 = -1/m1
A2=m2 B2=-1 C2=y3-m2*x3 A1=m1 B1=-1 C1=y1-m1*x1
end
local intsecPoint= solveLinearEquation(A1,B1,C1,A2,B2,C2)
if pointLiesOnLine(intsecPoint.x, intsecPoint.y,x1,y1,x2,y2) then
return dist(intsecPoint.x, intsecPoint.y, x3,y3)
else
return math.min(dist(x3,y3,x1,y1),dist(x3,y3,x2,y2))
end
end
``````

This answer is based on the accepted answer's JavaScript solution. It's mainly just formatted nicer, with longer function names, and of course shorter function syntax because it's in ES6 + CoffeeScript.

## JavaScript version (ES6)

``````distanceSquared = (v, w)=> Math.pow(v.x - w.x, 2) + Math.pow(v.y - w.y, 2);
distance = (v, w)=> Math.sqrt(distanceSquared(v, w));

distanceToLineSegmentSquared = (p, v, w)=> {
l2 = distanceSquared(v, w);
if (l2 === 0) {
return distanceSquared(p, v);
}
t = ((p.x - v.x) * (w.x - v.x) + (p.y - v.y) * (w.y - v.y)) / l2;
t = Math.max(0, Math.min(1, t));
return distanceSquared(p, {
x: v.x + t * (w.x - v.x),
y: v.y + t * (w.y - v.y)
});
}
distanceToLineSegment = (p, v, w)=> {
return Math.sqrt(distanceToLineSegmentSquared(p, v));
}
``````

## CoffeeScript version

``````distanceSquared = (v, w)-> (v.x - w.x) ** 2 + (v.y - w.y) ** 2
distance = (v, w)-> Math.sqrt(distanceSquared(v, w))

distanceToLineSegmentSquared = (p, v, w)->
l2 = distanceSquared(v, w)
return distanceSquared(p, v) if l2 is 0
t = ((p.x - v.x) * (w.x - v.x) + (p.y - v.y) * (w.y - v.y)) / l2
t = Math.max(0, Math.min(1, t))
distanceSquared(p, {
x: v.x + t * (w.x - v.x)
y: v.y + t * (w.y - v.y)
})

distanceToLineSegment = (p, v, w)->
Math.sqrt(distanceToLineSegmentSquared(p, v, w))
``````
• In the JS version, distance() is redundant, no? – ChrisJJ Mar 19 '17 at 10:23
• Yeah, in both versions it's unused. Feel free to remove it. – 1j01 Mar 21 '17 at 8:18

# in R

``````     #distance beetween segment ab and point c in 2D space
getDistance_ort_2 <- function(a, b, c){
#go to complex numbers
A<-c(a[1]+1i*a[2],b[1]+1i*b[2])
q=c[1]+1i*c[2]

#function to get coefficients of line (ab)
getAlphaBeta <- function(A)
{ a<-Re(A[2])-Re(A[1])
b<-Im(A[2])-Im(A[1])
ab<-as.numeric()
ab[1] <- -Re(A[1])*b/a+Im(A[1])
ab[2] <-b/a
if(Im(A[1])==Im(A[2])) ab<- c(Im(A[1]),0)
if(Re(A[1])==Re(A[2])) ab <- NA
return(ab)
}

#function to get coefficients of line ortogonal to line (ab) which goes through point q
getAlphaBeta_ort<-function(A,q)
{ ab <- getAlphaBeta(A)
coef<-c(Re(q)/ab[2]+Im(q),-1/ab[2])
if(Re(A[1])==Re(A[2])) coef<-c(Im(q),0)
return(coef)
}

#function to get coordinates of interception point
#between line (ab) and its ortogonal which goes through point q
getIntersection_ort <- function(A, q){
A.ab <- getAlphaBeta(A)
q.ab <- getAlphaBeta_ort(A,q)
if (!is.na(A.ab[1])&A.ab[2]==0) {
x<-Re(q)
y<-Im(A[1])}
if (is.na(A.ab[1])) {
x<-Re(A[1])
y<-Im(q)
}
if (!is.na(A.ab[1])&A.ab[2]!=0) {
x <- (q.ab[1] - A.ab[1])/(A.ab[2] - q.ab[2])
y <- q.ab[1] + q.ab[2]*x}
xy <- x + 1i*y
return(xy)
}

intersect<-getIntersection_ort(A,q)
if ((Mod(A[1]-intersect)+Mod(A[2]-intersect))>Mod(A[1]-A[2])) {dist<-min(Mod(A[1]-q),Mod(A[2]-q))
} else dist<-Mod(q-intersect)
return(dist)
}
``````

In javascript using Geometry:

``````var a = { x:20, y:20};//start segment
var b = { x:40, y:30};//end segment
var c = { x:37, y:14};//point

// magnitude from a to c
var ac = Math.sqrt( Math.pow( ( a.x - c.x ), 2 ) + Math.pow( ( a.y - c.y ), 2) );
// magnitude from b to c
var bc = Math.sqrt( Math.pow( ( b.x - c.x ), 2 ) + Math.pow( ( b.y - c.y ), 2 ) );
// magnitude from a to b (base)
var ab = Math.sqrt( Math.pow( ( a.x - b.x ), 2 ) + Math.pow( ( a.y - b.y ), 2 ) );
// perimeter of triangle
var p = ac + bc + ab;
// area of the triangle
var area = Math.sqrt( p/2 * ( p/2 - ac) * ( p/2 - bc ) * ( p/2 - ab ) );
// height of the triangle = distance
var h = ( area * 2 ) / ab;
console.log ("height: " + h);
``````
• nice idea, but height will be distance to line, in some cases distance to segment = distance to segment's start or end. – yolo sora Sep 7 '17 at 9:40

GLSL version:

``````// line (a -> b ) point p[enter image description here][1]
float distanceToLine(vec2 a, vec2 b, vec2 p) {
float aside = dot((p - a),(b - a));
if(aside< 0.0) return length(p-a);
float bside = dot((p - b),(a - b));
if(bside< 0.0) return length(p-b);
vec2 pointOnLine = (bside*a + aside*b)/pow(length(a-b),2.0);
return length(p - pointOnLine);
}
``````

Eigen C++ Version for 3D line segment and point

``````// Return minimum distance between line segment: head--->tail and point
double MinimumDistance(Eigen::Vector3d head, Eigen::Vector3d tail,Eigen::Vector3d point)
{
double l2 = std::pow((head - tail).norm(),2);

// Consider the line extending the segment, parameterized as head + t (tail - point).
// We find projection of point onto the line.
// We clamp t from [0,1] to handle points outside the segment head--->tail.

return (point - projection).norm();
}
``````

Here's a self contained Delphi / Pascal version of the function based on Joshua's answer up above. Uses TPoint for VCL screen graphics, but should be easy to adjust as needed.

``````function DistancePtToSegment( pt, pt1, pt2: TPoint): double;
var
a, b, c, d: double;
len_sq: double;
param: double;
xx, yy: double;
dx, dy: double;
begin
a := pt.x - pt1.x;
b := pt.y - pt1.y;
c := pt2.x - pt1.x;
d := pt2.y - pt1.y;

len_sq := (c * c) + (d * d);
param := -1;

if (len_sq <> 0) then
begin
param := ((a * c) + (b * d)) / len_sq;
end;

if param < 0 then
begin
xx := pt1.x;
yy := pt1.y;
end
else if param > 1 then
begin
xx := pt2.x;
yy := pt2.y;
end
else begin
xx := pt1.x + param * c;
yy := pt1.y + param * d;
end;

dx := pt.x - xx;
dy := pt.y - yy;
result := sqrt( (dx * dx) + (dy * dy))
end;
``````

Solution for dart and flutter:

``````import 'dart:math' as math;
class Utils {
static double shortestDistance(Point p1, Point p2, Point p3){
double px = p2.x - p1.x;
double py = p2.y - p1.y;
double temp = (px*px) + (py*py);
double u = ((p3.x - p1.x)*px + (p3.y - p1.y)* py) /temp;
if(u>1){
u=1;
}
else if(u<0){
u=0;
}
double x = p1.x + u*px;
double y = p1.y + u*py;
double dx = x - p3.x;
double dy = y - p3.y;
double dist = math.sqrt(dx*dx+dy*dy);
return dist;
}
}

class Point {
double x;
double y;
Point(this.x, this.y);
}
``````