# Direct way of computing clockwise angle between 2 vectors

I want to find out the clockwise angle between 2 vectors(2D, 3D).

The clasic way with the dot product gives me the inner angle(0-180 degrees) and I need to use some if statements to determine if the result is the angle I need or its complement.

Do you know a direct way of computing clockwise angle?

• Why not use `std::atan2()`? – user529758 Dec 28 '12 at 8:53
• How do you define "clockwise angle" for vectors in 3D? – Martin R Dec 28 '12 at 9:13
• @H2CO3 This seems the best solution for 2D angles. – Mircea Ispas Dec 28 '12 at 9:14
• @MartinR "clockwise" is a generic term to say I want the angle in a specific "direction", not in the nearest "direction". Nickolay O. specified in his answer a way of describind this "direction" – Mircea Ispas Dec 28 '12 at 9:17
• @Felics: "clockwise" is well-defined in 2D, but not in 3D. Checking the z-coordinate of the cross product (as in Nickolay O.'s answer) would mean in 3D: "clockwise for an observer looking from above on the x/y plane." – Martin R Dec 28 '12 at 9:34

# 2D case

Just like the dot product is proportional to the cosine of the angle, the determinant is proprortional to its sine. So you can compute the angle like this:

``````dot = x1*x2 + y1*y2      # dot product between [x1, y1] and [x2, y2]
det = x1*y2 - y1*x2      # determinant
angle = atan2(det, dot)  # atan2(y, x) or atan2(sin, cos)
``````

The orientation of this angle matches that of the coordinate system. In a left-handed coordinate system, i.e. x pointing right and y down as is common for computer graphics, this will mean you get a positive sign for clockwise angles. If the orientation of the coordinate system is mathematical with y up, you get counter-clockwise angles as is the convention in mathematics. Changing the order of the inputs will change the sign, so if you are unhappy with the signs just swap the inputs.

# 3D case

In 3D, two arbitrarily placed vectors define their own axis of rotation, perpendicular to both. That axis of rotation does not come with a fixed orientation, which means that you cannot uniquely fix the direction of the angle of rotation either. One common convention is to let angles be always positive, and to orient the axis in such a way that it fits a positive angle. In this case, the dot product of the normalized vectors is enough to compute angles.

``````dot = x1*x2 + y1*y2 + z1*z2    #between [x1, y1, z1] and [x2, y2, z2]
lenSq1 = x1*x1 + y1*y1 + z1*z1
lenSq2 = x2*x2 + y2*y2 + z2*z2
angle = acos(dot/sqrt(lenSq1 * lenSq2))
``````

# Plane embedded in 3D

One special case is the case where your vectors are not placed arbitrarily, but lie within a plane with a known normal vector n. Then the axis of rotation will be in direction n as well, and the orientation of n will fix an orientation for that axis. In this case, you can adapt the 2D computation above, including n into the determinant to make its size 3×3.

``````dot = x1*x2 + y1*y2 + z1*z2
det = x1*y2*zn + x2*yn*z1 + xn*y1*z2 - z1*y2*xn - z2*yn*x1 - zn*y1*x2
angle = atan2(det, dot)
``````

One condition for this to work is that the normal vector n has unit length. If not, you'll have to normalize it.

## As triple product

This determinant could also be expressed as the triple product, as @Excrubulent pointed out in a suggested edit.

``````det = n · (v1 × v2)
``````

This might be easier to implement in some APIs, and gives a different perspective on what's going on here: The cross product is proportional to the sine of the angle, and will lie perpendicular to the plane, hence be a multiple of n. The dot product will therefore basically measure the length of that vector, but with the correct sign attached to it.

• Have an upvote - I can't be bothered figuring out if the other answers are correct or not, yours is the clearest and most readable, so it's the one that helped me. – Excrubulent Jul 18 '13 at 15:22
• For the 2D I'm getting (0,180) and (-180,0). One can check when the result is negative and add 360 in order to get a nice clockwise angle (for example if it's -180 adding 360 results in 180, for -90 adding 360 results in 270 etc.). Don't know if it's just my calculation or the implementation of the `qAtan2(y, x)` (from the Qt framework) but if someone has the same problem as me this might help. – rbaleksandar Dec 13 '16 at 18:35
• @rbaleksandar: `atan2` usually is in the range [-180°,180°]. To get [0°,360°] without a case distinction, one can replace `atan2(y,x)` with `atan2(-y,-x) + 180°`. – MvG Dec 13 '16 at 18:54
• @jianz: The angle is the positive angle with respect to the coordinate system. If x is right and y is up, then the angle is counter-clockwise. If y is down, it's clockwise. Most computer graphics environments use the latter. If you want to reverse the orientation, simply change the order of the inputs, which will flip the sign of the determinant. – MvG Dec 15 '17 at 10:35
• Noooooo don't ever take acos of a dot product! That's mathematically correct but horribly inaccurate in practice. You could replace your 3d method with another atan2(det,dot); in this case det would be the length of the cross product. – Don Hatch Dec 13 '18 at 9:17

To compute angle you just need to call `atan2(v1.s_cross(v2), v1.dot(v2))` for 2D case. Where `s_cross` is scalar analogue of cross production (signed area of parallelogram). For 2D case that would be wedge production. For 3D case you need to define clockwise rotation because from one side of plane clockwise is one direction, from other side of plane is another direction =)

Edit: this is counter clockwise angle, clockwise angle is just opposite

• v1.cross(v2) is a vector, not a scalar and can't be used like this. Nickolay O. describes in his answer how to find out 'direction' of the angle. One way to get 2D angle is: angle = atan2f(v2.x, v2.y) - atan2f(v1.x, v1.y) – Mircea Ispas Dec 28 '12 at 9:27
• @Felics In 2D cross production often means wedge production en.wikipedia.org/wiki/Wedge_product That is signed area of parallelogram. For 2D case that formula is absolutely correct as it dot = |v1||v2|*cos and cross = |v1||v2|sin. That is why atan2 gives correct angle in whole circle range. And as I said for 3d case you need to make some assumptions to have some extension of clockwise orientation – kassak Dec 28 '12 at 9:35
• @Felics: Note that `atan2f` has the y-coordinate as first argument, so it should be `angle = atan2f(v2.y, v2.x) - atan2f(v1.y, v1.x)`. – Martin R Dec 28 '12 at 9:38
• @kassak: You could replace `cross` and `dot` by the explicit formula in the 2D case, that would remove all doubts about `cross` returning a 3D vector (but that is only a suggestion, which you can ignore). - Otherwise I like this solution, because it requires only one `atan2f` function call. – Martin R Dec 28 '12 at 9:45
• @Martin R thanks for good advice. I've made some corrections to make meaning of formula clearer – kassak Dec 28 '12 at 9:50

This answer is the same as MvG's, but explains it differently (it's the result of my efforts in trying to understand why MvG's solution works). I'm posting it on the off chance that others find it helpful.

The anti-clockwise angle `theta` from `x` to `y`, with respect to the viewpoint of their given normal `n` (`||n|| = 1`), is given by

atan2( dot(n, cross(x,y)), dot(x,y) )

(1) = atan2( ||x|| ||y|| sin(theta),  ||x|| ||y|| cos(theta) )

(2) = atan2( sin(theta), cos(theta) )

(3) = anti-clockwise angle between x axis and the vector (cos(theta), sin(theta))

(4) = theta

where `||x||` denotes the magnitude of `x`.

Step (1) follows by noting that

cross(x,y) = ||x|| ||y|| sin(theta) n,

and so

dot(n, cross(x,y))

= dot(n, ||x|| ||y|| sin(theta) n)

= ||x|| ||y|| sin(theta) dot(n, n)

which equals

||x|| ||y|| sin(theta)

if `||n|| = 1`.

Step (2) follows from the definition of `atan2`, noting that `atan2(cy, cx) = atan2(y,x)`, where `c` is a scalar. Step (3) follows from the definition of `atan2`. Step (4) follows from the geometric definitions of `cos` and `sin`.

Scalar (dot) product of two vectors lets you get the cosinus of the angle between them. To get the 'direction' of the angle, you should also calculate the cross product, it will let you check (via z coordinate) is angle is clockwise or not (i.e. should you extract it from 360 degrees or not).

• Even this is correct it is what I want to avoid - to compute some value and determine if the computed value represents my angle or my angle's complement. – Mircea Ispas Dec 28 '12 at 9:13
• I want to know if this is possible:) Why to use some ineficient way of doing things if there is (maybe!) a better way. If there is no better way I will the "standard" thing, but it's always good to ask for better! – Mircea Ispas Dec 28 '12 at 13:37
• Actually, standard ways not always efficient ) – Nickolay Olshevsky Dec 28 '12 at 19:52
• @NickolayOlshevsky What do you mean exactly by check via z coordinate, how can I go about doing this? – Ogen Apr 12 '14 at 14:36
• You should check the sign of z coordinate, as far as I remember. – Nickolay Olshevsky Apr 13 '14 at 15:36

For a 2D method, you could use the law of cosines and the "direction" method.

To calculate the angle of segment P3:P1 sweeping clockwise to segment P3:P2.

```
P1     P2

P3
```
``````    double d = direction(x3, y3, x2, y2, x1, y1);

// c
int d1d3 = distanceSqEucl(x1, y1, x3, y3);

// b
int d2d3 = distanceSqEucl(x2, y2, x3, y3);

// a
int d1d2 = distanceSqEucl(x1, y1, x2, y2);

//cosine A = (b^2 + c^2 - a^2)/2bc
double cosA = (d1d3 + d2d3 - d1d2)
/ (2 * Math.sqrt(d1d3 * d2d3));

double angleA = Math.acos(cosA);

if (d > 0) {
angleA = 2.*Math.PI - angleA;
}

This has the same number of transcendental
``````

operations as suggestions above and only one more or so floating point operation.

the methods it uses are:

`````` public int distanceSqEucl(int x1, int y1,
int x2, int y2) {

int diffX = x1 - x2;
int diffY = y1 - y2;
return (diffX * diffX + diffY * diffY);
}

public int direction(int x1, int y1, int x2, int y2,
int x3, int y3) {

int d = ((x2 - x1)*(y3 - y1)) - ((y2 - y1)*(x3 - x1));

return d;
}
``````

If by "direct way" you mean avoiding the `if` statement, then I don't think there is a really general solution.

However, if your specific problem would allow loosing some precision in angle discretization and you are ok with loosing some time in type conversions, you can map the [-pi,pi) allowed range of phi angle onto the allowed range of some signed integer type. Then you would get the complementarity for free. However, I didn't really use this trick in practice. Most likely, the expense of float-to-integer and integer-to-float conversions would outweigh any benefit of the directness. It's better to set your priorities on writing autovectorizable or parallelizable code when this angle computation is done a lot.

Also, if your problem details are such that there is a definite more likely outcome for the angle direction, then you can use compilers' builtin functions to supply this information to the compiler, so it can optimize the branching more efficiently. E.g., in case of gcc, that's `__builtin_expect` function. It's somewhat more handy to use when you wrap it into such `likely` and `unlikely` macros (like in linux kernel):

``````#define likely(x)      __builtin_expect(!!(x), 1)
#define unlikely(x)    __builtin_expect(!!(x), 0)
``````

A formula for clockwise angle,2D case, between 2 vectors, xa,ya and xb,yb.

Angle(vec.a-vec,b)=pi()/2*((1+sign(ya))* (1-sign(xa^2))-(1+sign(yb))* (1-sign(xb^2)))

``````                        +pi()/4*((2+sign(ya))*sign(xa)-(2+sign(yb))*sign(xb))

+sign(xa*ya)*atan((abs(ya)-abs(xa))/(abs(ya)+abs(xa)))

-sign(xb*yb)*atan((abs(yb)-abs(xb))/(abs(yb)+abs(xb)))
``````

just copy & paste this.

``````angle = (acos((v1.x * v2.x + v1.y * v2.y)/((sqrt(v1.x*v1.x + v1.y*v1.y) * sqrt(v2.x*v2.x + v2.y*v2.y))))/pi*180);
``````

you're welcome ;-)

• Although this code snippet may answer the question, including an explanation of why and how it helps solve the problem improves the quality and longevity of your answer, especially regarding older questions like this. See "How do I write a good answer?". – slothiful Jun 29 '19 at 14:34