# Sort points in clockwise order?

Given an array of x,y points, how do I sort the points of this array in clockwise order (around their overall average center point)? My goal is to pass the points to a line-creation function to end up with something looking rather "solid", as convex as possible with no lines intersecting.

For what it's worth, I'm using Lua, but any pseudocode would be appreciated.

Update: For reference, this is the Lua code based on Ciamej's excellent answer (ignore my "app" prefix):

``````function appSortPointsClockwise(points)
local centerPoint = appGetCenterPointOfPoints(points)
app.pointsCenterPoint = centerPoint
table.sort(points, appGetIsLess)
return points
end

function appGetIsLess(a, b)
local center = app.pointsCenterPoint

if a.x >= 0 and b.x < 0 then return true
elseif a.x == 0 and b.x == 0 then return a.y > b.y
end

local det = (a.x - center.x) * (b.y - center.y) - (b.x - center.x) * (a.y - center.y)
if det < 0 then return true
elseif det > 0 then return false
end

local d1 = (a.x - center.x) * (a.x - center.x) + (a.y - center.y) * (a.y - center.y)
local d2 = (b.x - center.x) * (b.x - center.x) + (b.y - center.y) * (b.y - center.y)
return d1 > d2
end

function appGetCenterPointOfPoints(points)
local pointsSum = {x = 0, y = 0}
for i = 1, #points do pointsSum.x = pointsSum.x + points[i].x; pointsSum.y = pointsSum.y + points[i].y end
return {x = pointsSum.x / #points, y = pointsSum.y / #points}
end
``````

• Think about compute the angle of the radial line through that point. Then sort by angle. Aug 8, 2011 at 22:00
• In case you didn't know, lua has a builtin function `ipairs(tbl)` that iterates over the indices and values of tbl from 1 to #tbl. So for the sum calculation, you can do this, which most people find looks cleaner: `for _, p in ipairs(points) do pointsSum.x = pointsSum.x + p.x; pointsSum.y = pointsSum.y + p.y end` Aug 15, 2011 at 17:49
• @Wallacoloo That's highly arguable. Also, in vanilla Lua `ipairs` is significantly slower than numeric for loop. Oct 5, 2011 at 9:43
• I had to make some small changes to get it to work for my case (just comparing two points relative to a centre). gist.github.com/personalnadir/6624172 All those comparisons to 0 in the code seem to assume that the points are distributed around the origin, as opposed to an arbitrary point. I also think that first condition will sort points below the centre point incorrectly. Thanks for the code though, it's been really helpful! Sep 19, 2013 at 14:18

First, compute the center point. Then sort the points using whatever sorting algorithm you like, but use special comparison routine to determine whether one point is less than the other.

You can check whether one point (a) is to the left or to the right of the other (b) in relation to the center by this simple calculation:

``````det = (a.x - center.x) * (b.y - center.y) - (b.x - center.x) * (a.y - center.y)
``````

if the result is zero, then they are on the same line from the center, if it's positive or negative, then it is on one side or the other, so one point will precede the other. Using it you can construct a less-than relation to compare points and determine the order in which they should appear in the sorted array. But you have to define where is the beginning of that order, I mean what angle will be the starting one (e.g. the positive half of x-axis).

The code for the comparison function can look like this:

``````bool less(point a, point b)
{
if (a.x - center.x >= 0 && b.x - center.x < 0)
return true;
if (a.x - center.x < 0 && b.x - center.x >= 0)
return false;
if (a.x - center.x == 0 && b.x - center.x == 0) {
if (a.y - center.y >= 0 || b.y - center.y >= 0)
return a.y > b.y;
return b.y > a.y;
}

// compute the cross product of vectors (center -> a) x (center -> b)
int det = (a.x - center.x) * (b.y - center.y) - (b.x - center.x) * (a.y - center.y);
if (det < 0)
return true;
if (det > 0)
return false;

// points a and b are on the same line from the center
// check which point is closer to the center
int d1 = (a.x - center.x) * (a.x - center.x) + (a.y - center.y) * (a.y - center.y);
int d2 = (b.x - center.x) * (b.x - center.x) + (b.y - center.y) * (b.y - center.y);
return d1 > d2;
}
``````

This will order the points clockwise starting from the 12 o'clock. Points on the same "hour" will be ordered starting from the ones that are further from the center.

If using integer types (which are not really present in Lua) you'd have to assure that det, d1 and d2 variables are of a type that will be able to hold the result of performed calculations.

If you want to achieve something looking solid, as convex as possible, then I guess you're looking for a Convex Hull. You can compute it using the Graham Scan. In this algorithm, you also have to sort the points clockwise (or counter-clockwise) starting from a special pivot point. Then you repeat simple loop steps each time checking if you turn left or right adding new points to the convex hull, this check is based on a cross product just like in the above comparison function.

Edit:

Added one more if statement `if (a.y - center.y >= 0 || b.y - center.y >=0)` to make sure that points that have x=0 and negative y are sorted starting from the ones that are further from the center. If you don't care about the order of points on the same 'hour' you can omit this if statement and always return `a.y > b.y`.

Corrected the first if statements with adding `-center.x` and `-center.y`.

Added the second if statement `(a.x - center.x < 0 && b.x - center.x >= 0)`. It was an obvious oversight that it was missing. The if statements could be reorganized now because some checks are redundant. For example, if the first condition in the first if statement is false, then the first condition of the second if must be true. I decided, however, to leave the code as it is for the sake of simplicity. It's quite possible that the compiler will optimize the code and produce the same result anyway.

• +1: No `atan()`, no square root, and even no divisions. This is a good example of computer graphics thinking. Cull off all the easy cases as soon as possible, and even in the hard cases, compute as little as possible to know the required answer. Aug 9, 2011 at 1:29
• if the set of points is known a priori it only takes O(n*log n) comparisons. If you want to add points in the meantime then you need to keep them in a sorted set such as a balanced binary search tree. In such a case adding a new point requires O(log n) comparisons and it's exactly the same for the solution involving polar coordinates. Aug 9, 2011 at 1:49
• Is this missing the case: if (a.x - center.x < 0 && b.x - center.x >= 0) return false; Mar 3, 2014 at 23:38
• Hey there. It's pretty old, but: "This will order the points clockwise starting from the 12 o'clock." Why 12 o'clock and how can I change it to 6? Can anybody tell me? Sep 19, 2016 at 10:27
• For anyone looking for more information, this uses the cross-product between vectors. Jun 2, 2017 at 16:51

What you're asking for is a system known as polar coordinates. Conversion from Cartesian to polar coordinates is easily done in any language. The formulas can be found in this section.

After converting to polar coordinates, just sort by the angle, theta.

• This will work, but it will also have the defect of doing more computation than needed to answer the ordering question. In practice, you don't actually care about either the actual angles or radial distances, just their relative order. ciamej's solution is better because it avoids divisions, square roots, and trig. Aug 9, 2011 at 1:28
• I'm not sure what your criterion is for "better". For instance, comparing all points to each other is kind of a waste of computation. Trig isn't something that scares adults, is it? Aug 9, 2011 at 1:42
• It's not that trig is scary. The issue is that trig is expensive to compute, and wasn't needed to determine the relative order of the angles. Similarly, you don't need to take the square roots to put the radii in order. A full conversion from Cartesian to polar coordinates will do both an arc-tangent and a square root. Hence your answer is correct, but in the context of computer graphics or computational geometry it is likely to not be the best way to do it. Aug 9, 2011 at 1:51
• Got it. However, the OP didn't post as comp-geo, that was a tag by someone else. Still, it looks like the other solution is polynomial in the # of points, or am I mistaken? If so, that burns more cycles than trig. Aug 9, 2011 at 1:53
• I'm glad to help. Thanks for the clarification on the usage & speed interest. My answer was focused on simplicity of understanding, but @ciamej's answer is certainly more computationally efficient. I'm glad this Q&A arose - I didn't realize that a comp-geo community was on SO, and I've learned something. I'll likely tap the comp-geo community expertise for some other problems. :) Aug 10, 2011 at 12:57

An interesting alternative approach to your problem would be to find the approximate minimum to the Traveling Salesman Problem (TSP), ie. the shortest route linking all your points. If your points form a convex shape, it should be the right solution, otherwise, it should still look good (a "solid" shape can be defined as one that has a low perimeter/area ratio, which is what we are optimizing here).

You can use any implementation of an optimizer for the TSP, of which I am pretty sure you can find a ton in your language of choice.

• Yikes. "Interesting" is an understatement. :) Aug 10, 2011 at 20:02
• @Iterator: I was quite happy with my idea, I was pretty disappointed to get downvoted for it :-/ Do you think it's valid? Aug 11, 2011 at 6:45
• I was suggesting to use one of the many fast approximations, not the NP-complete original algorithm, of course. Aug 11, 2011 at 12:13
• I appreciate the additional angle! To have several valid, if very different answers, might be of great help if someone in the future happens to stumble on this thread looking to brainstorm options. Aug 12, 2011 at 9:14
• Note that my approach is probably slower, but more correct in complex cases: imagine the case where the points for an "8", for example. Polar coordinates aren't going to help you in that case, and the result you will obtain will heavily depend on the center you chose. The TSP solution is independent of any "heuristic" parameters. Aug 12, 2011 at 9:40

Another version (return true if a comes before b in counterclockwise direction):

``````    bool lessCcw(const Vector2D &center, const Vector2D &a, const Vector2D &b) const
{
// Computes the quadrant for a and b (0-3):
//     ^
//   1 | 0
//  ---+-->
//   2 | 3

const int dax = ((a.x() - center.x()) > 0) ? 1 : 0;
const int day = ((a.y() - center.y()) > 0) ? 1 : 0;
const int qa = (1 - dax) + (1 - day) + ((dax & (1 - day)) << 1);

/* The previous computes the following:

const int qa =
(  (a.x() > center.x())
? ((a.y() > center.y())
? 0 : 3)
: ((a.y() > center.y())
? 1 : 2)); */

const int dbx = ((b.x() - center.x()) > 0) ? 1 : 0;
const int dby = ((b.y() - center.y()) > 0) ? 1 : 0;
const int qb = (1 - dbx) + (1 - dby) + ((dbx & (1 - dby)) << 1);

if (qa == qb) {
return (b.x() - center.x()) * (a.y() - center.y()) < (b.y() - center.y()) * (a.x() - center.x());
} else {
return qa < qb;
}
}
``````

This is faster, because the compiler (tested on Visual C++ 2015) doesn't generate jump to compute dax, day, dbx, dby. Here the output assembly from the compiler:

``````; 28   :    const int dax = ((a.x() - center.x()) > 0) ? 1 : 0;

vmovss  xmm2, DWORD PTR [ecx]
vmovss  xmm0, DWORD PTR [edx]

; 29   :    const int day = ((a.y() - center.y()) > 0) ? 1 : 0;

vmovss  xmm1, DWORD PTR [ecx+4]
vsubss  xmm4, xmm0, xmm2
vmovss  xmm0, DWORD PTR [edx+4]
push    ebx
xor ebx, ebx
vxorps  xmm3, xmm3, xmm3
vcomiss xmm4, xmm3
vsubss  xmm5, xmm0, xmm1
seta    bl
xor ecx, ecx
vcomiss xmm5, xmm3
push    esi
seta    cl

; 30   :    const int qa = (1 - dax) + (1 - day) + ((dax & (1 - day)) << 1);

mov esi, 2
push    edi
mov edi, esi

; 31   :
; 32   :    /* The previous computes the following:
; 33   :
; 34   :    const int qa =
; 35   :        (   (a.x() > center.x())
; 36   :         ? ((a.y() > center.y()) ? 0 : 3)
; 37   :         : ((a.y() > center.y()) ? 1 : 2));
; 38   :    */
; 39   :
; 40   :    const int dbx = ((b.x() - center.x()) > 0) ? 1 : 0;

xor edx, edx
lea eax, DWORD PTR [ecx+ecx]
sub edi, eax
lea eax, DWORD PTR [ebx+ebx]
and edi, eax
mov eax, DWORD PTR _b\$[esp+8]
sub edi, ecx
sub edi, ebx
vmovss  xmm0, DWORD PTR [eax]
vsubss  xmm2, xmm0, xmm2

; 41   :    const int dby = ((b.y() - center.y()) > 0) ? 1 : 0;

vmovss  xmm0, DWORD PTR [eax+4]
vcomiss xmm2, xmm3
vsubss  xmm0, xmm0, xmm1
seta    dl
xor ecx, ecx
vcomiss xmm0, xmm3
seta    cl

; 42   :    const int qb = (1 - dbx) + (1 - dby) + ((dbx & (1 - dby)) << 1);

lea eax, DWORD PTR [ecx+ecx]
sub esi, eax
lea eax, DWORD PTR [edx+edx]
and esi, eax
sub esi, ecx
sub esi, edx

; 43   :
; 44   :    if (qa == qb) {

cmp edi, esi
jne SHORT \$LN37@lessCcw

; 45   :        return (b.x() - center.x()) * (a.y() - center.y()) < (b.y() - center.y()) * (a.x() - center.x());

vmulss  xmm1, xmm2, xmm5
vmulss  xmm0, xmm0, xmm4
xor eax, eax
pop edi
vcomiss xmm0, xmm1
pop esi
seta    al
pop ebx

; 46   :    } else {
; 47   :        return qa < qb;
; 48   :    }
; 49   : }

ret 0
\$LN37@lessCcw:
pop edi
pop esi
setl    al
pop ebx
ret 0
?lessCcw@@YA_NABVVector2D@@00@Z ENDP            ; lessCcw
``````

Enjoy.

• The two return statements in the switch are mathematically equivalent. Is there a reason for having the switch? Aug 22, 2018 at 2:55
• To anyone looking for the `switch` (mentioned by @unagi): It has been edited out since. Dec 20, 2022 at 22:13
• vector3 a = new vector3(1 , 0 , 0)..............w.r.t X_axis
• vector3 b = any_point - Center;
``````- y = |a * b|   ,   x =  a . b

- Atan2(y , x)...............................gives angle between -PI  to  + PI  in radians
- (Input % 360  +  360) % 360................to convert it from  0 to 2PI in radians
- sort by adding_points to list_of_polygon_verts by angle  we got 0  to 360

``````

Finally you get Anticlockwize sorted verts

list.Reverse()..................Clockwise_order

I know this is somewhat of an old post with an excellent accepted answer, but I feel like I can still contribute something useful. All the answers so far essentially use a comparison function to compare two points and determine their order, but what if you want to use only one point at a time and a key function?

Not only is this possible, but the resulting code is also extremely compact. Here is the complete solution using Python's built-in sorted function:

``````# Create some random points
num = 7
points = np.random.random((num, 2))
# Compute their center
center = np.mean(points, axis=0)

# Make arctan2 function that returns a value from [0, 2 pi) instead of [-pi, pi)
arctan2 = lambda s, c: angle if (angle := np.arctan2(s, c)) >= 0 else 2 * np.pi + angle

# Define the key function
def clockwise_around_center(point):
diff = point - center
rcos = np.dot(diff, center)
rsin = np.cross(diff, center)
return arctan2(rsin, rcos)

# Sort our points using the key function
sorted_points = sorted(points, key=clockwise_around_center)

``````

This answer would also work in 3D, if the points are on a 2D plane embedded in 3D. We would only have to modify the calculation of `rsin` by dotting it with the normal vector of the plane. E.g.

``````rsin = np.dot([0,0,1], np.cross(diff, center))
``````

if that plane has `e_z` as its normal vector.

The advantage of this code is that it works on only one point at the time using a key function. The quantity `rsin`, if you work it out on a coefficient level, is exactly the same as what is called `det` in the accepter answer, except that I compute it between `point - center` and `center`, not between `point1 - center` and `point2 - center`. But the geometrical meaning of this quantity is the radius times the sin of the angle, hence I call this variable `rsin`. Similarly for the dot product, which is the radius times the cosine of the angle and hence called `rcos`.

One could argue that this solution uses `arctan2`, and is therefore less clean. However, I personally think that the clearity of using a key function outweighs the need for one call to a trig function. Note that I prefer to have `arctan2` return a value from `[0, 2 pi)`, because then we get the angle `0` when `point` happens to be identical to `center`, and thus it will be the first point in our sorted list. This is an optional choice.

In order to understand why this code works, the crucial insight is that all our points are defined as arrows with respect to the origin, including the `center` point itself. So if we calculate `point - center`, this is equivalent to placing the arrow from the tip of `center` to the tip of `point`, at the origin. Hence we can sort the arrow `point - center` with respect to the angle it makes with the arrow pointing to `center`.

Here's a way to sort the vertices of a rectangle in clock-wise order. I modified the original solution provided by pyimagesearch and got rid of the scipy dependency.

``````import numpy as np

def pointwise_distance(pts1, pts2):
"""Calculates the distance between pairs of points

Args:
pts1 (np.ndarray): array of form [[x1, y1], [x2, y2], ...]
pts2 (np.ndarray): array of form [[x1, y1], [x2, y2], ...]

Returns:
np.array: distances between corresponding points
"""
dist = np.sqrt(np.sum((pts1 - pts2)**2, axis=1))
return dist

def order_points(pts):
"""Orders points in form [top left, top right, bottom right, bottom left].
Source: https://www.pyimagesearch.com/2016/03/21/ordering-coordinates-clockwise-with-python-and-opencv/

Args:
pts (np.ndarray): list of points of form [[x1, y1], [x2, y2], [x3, y3], [x4, y4]]

Returns:
[type]: [description]
"""
# sort the points based on their x-coordinates
x_sorted = pts[np.argsort(pts[:, 0]), :]

# grab the left-most and right-most points from the sorted
# x-roodinate points
left_most = x_sorted[:2, :]
right_most = x_sorted[2:, :]

# now, sort the left-most coordinates according to their
# y-coordinates so we can grab the top-left and bottom-left
# points, respectively
left_most = left_most[np.argsort(left_most[:, 1]), :]
tl, bl = left_most

# now that we have the top-left coordinate, use it as an
# anchor to calculate the Euclidean distance between the
# top-left and right-most points; by the Pythagorean
# theorem, the point with the largest distance will be
# our bottom-right point. Note: this is a valid assumption because
# we are dealing with rectangles only.
# We need to use this instead of just using min/max to handle the case where
# there are points that have the same x or y value.
D = pointwise_distance(np.vstack([tl, tl]), right_most)

br, tr = right_most[np.argsort(D)[::-1], :]

# return the coordinates in top-left, top-right,
# bottom-right, and bottom-left order
return np.array([tl, tr, br, bl], dtype="float32")

``````

With numpy:

``````import matplotlib.pyplot as plt
import numpy as np

# List of coords
coords = np.array([7,7, 5, 0, 0, 0, 5, 10, 10, 0, 0, 5, 10, 5, 0, 10, 10, 10]).reshape(-1, 2)
centroid = np.mean(coords, axis=0)
sorted_coords = coords[np.argsort(np.arctan2(coords[:, 1] - centroid, coords[:, 0] - centroid)), :]

plt.scatter(coords[:,0],coords[:,1])
plt.plot(coords[:,0],coords[:,1])
plt.plot(sorted_coords[:,0],sorted_coords[:,1])
plt.show()
`````` 