# Different methods for finding angle between two vectors

Last year I learnt at a school, in a C++ game dev class, that to find the angle between two vectors you could use this method:

vec2_t is defined as: `typedef float vec2_t[2];` vec[0] = x and vec[1] = y

``````float VectorAngle(vec2_t a, vec2_t b)
{
vec2_t vUp;
vec2_t vRight;
vec2_t vDir;
float dot, side, angle;

VectorCopy(vUp, a);
VectorNormalize(vUp);

VectorInit(vRight, -vUp[1], vUp[0]);

VectorCopy(vDir, b);
VectorNormalize(vDir);

dot = VectorDot(vUp, vDir);
side = VectorDot(vRight, vDir);
angle = acosf(dot);

if(side < 0.0f)
angle *= -1.0f;

return angle;
}
``````

Then just yesterday while looking for a solution to something else I found you could use this method instead:

``````float VectorAngle(vec2_t a, vec2_t b)
{
return atan2f(b[1]-a[1], b[0]-a[0]);
}
``````

This seems much more simple to implement... my question is, why would one favour one method over the second one when the second one is much more simple?

EDIT: Just to make sure: If vector a is [100, 100] and vector b is [300, 300] then method 2 returns 0.78539819 radians, is this correct?

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Does method 2 actually give the right answer? It seems to me that it does not. – yiding Dec 21 '12 at 4:24
I'm using it now and it seems like it does. – Tom Tetlaw Dec 21 '12 at 4:25
the angle between (100, 100) and (300, 300) is 0, because they are pointing in exactly the same direction. – yiding Dec 21 '12 at 4:29
That's weird because when I create a vector that is [0.78539819*dist[0], 0.78539819*dist[1]] and use that as a velocity it the object that started at (100, 100) goes in the direction towards the object at (300, 300) (dist is the distance between (100,100) and (300,300)) – Tom Tetlaw Dec 21 '12 at 4:31
what is `dist`? – yiding Dec 21 '12 at 4:32

You can use complex numbers for 2d vector calculations. Multiplication of complex numbers can be seen as a positive rotation, and division as a negative rotation. We want to use division as it acts to subtract one angle from the other:

``````#include <complex>

int main() {
using std::complex;
using std::arg;

complex<double> a, b;

double angle = arg(a/b);

return 0;
}
``````
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The second method calculates the geometric difference vector for b and a (b-a) and returns the angle between this difference and X axis, Obviously such angle is not generelly equal to angle between a and b.

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A method I find usable:

``````        // cross product
double y = (v1[0] * v2[1]) - (v2[0] * v1[1]);

// dot product
double x = (v1[0] * v2[0]) + (v1[1] * v2[1]);

return atan2(y, x);
``````
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Compare the acosf source to atanf2f source to see difference in implementations. The latter uses a table which might be infeasible for some systems.

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