# Non-axis aligned scaling

Finding a good way to do this has stumped me for a while now: assume I have a selection box with a set of points in it. By dragging the corners you can scale the (distance between) points in the box. Now for an axis aligned box this is easy. Take a corner as an anchor point (subtract this corner from each point, scale it, then add it to the point again) and multiply each points x and y by the factor with which the box has gotten bigger.

But now take a box that is not aligned with the x and y axis. How do you scale the points inside this box when you drag its corners?

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You pick one corner of the rectangle as the origin. The two edges connected to it will be the basis (`u` and `v`, which should be perpendicular to each other). You would need to normalize them first.

Subtract the origin from the coordinates and calculate the dot-product with the scaling vector (`u`), and with the other vector (`v`). This would give you how much `u` and `v` contributes to the coordinate.

Then you scale the component you want. To get the final coordinate, you just multiply the the (now scaled) components with their respective vector, and add them together.

For example:

``````Points: p1 = (3,5) and p2 = (6,4)

Selection corners: (0,2),(8,0),(9,4),(1,6)
selected origin = (8,0)

u = ((0,2)-(8,0))/|(0,2)-(8,0)| = <-0.970, 0.242>
v = <-0.242, -0.970>
``````

(`v` is `u`, but with flipped coordinates, and one of them negated)

``````p1´ = p1 - origin = (-5, 5)
p2´ = p2 - origin = (-2, 4)

p1_u = p1´ . u = -0.970 * (-5) + 0.242 * 5 = 6.063
p1_v = p1´ . v = -0.242 * (-5) - 0.970 * 5 = -3.638

Scale p1_u by 0.5: 3.038

p1_u * u + p1_v * v + origin = <5.941, 4.265>

Same for p2: <7.412, 3.647>
``````

As you maybe can see, they have moved towards the line `(8,0)`-`(9,4)`, since we scaled by 0.5, with `(0,8)` as the origin.

Edit: This turned out to be a little harder to explain than I anticipated.

In python code, it could look something like this:

``````def scale(points, origin, u, scale):
# normalize
len_u = (u[0]**2 + u[1]**2) ** 0.5
u = (u[0]/len_u, u[1]/len_u)
# create v
v = (-u[1],u[0])
ret = []
for x,y in points:
# subtract origin
x, y = x - origin[0], y - origin[1]
# calculate dot product
pu = x * u[0] + y * u[1]
pv = x * v[0] + y * v[1]
# scale
pu = pu * scale
# transform back to normal space
x = pu * u[0] + pv * v[0] + origin[0]
y = pu * u[1] + pv * v[1] + origin[1]
ret.append((x,y))
return ret

>>> scale([(3,5),(6,4)],(8,0),(-8,2),0.5)
[(5.9411764705882355, 4.2647058823529411), (7.4117647058823533, 3.6470588235294117)]
``````
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Any box is contained inside a circle.
You find the circle which binds the box, find its center and do exactly the same as you do with an axis aligned box.

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elegant and correct –  Charles Bretana Dec 2 '08 at 22:25
You've just replaced one problem with another. How do you get the circle which binds the box? –  Mark Ransom Dec 2 '08 at 22:28
simple geometry. –  shoosh Dec 3 '08 at 2:01
The center of the box is (p1+p3)/2 where p1 and p3 are opposite points. The angles in the corners of the box need not be 90°, it's sufficient that opposite angles are the same (parallelogram) –  Aaron Digulla Dec 3 '08 at 8:52
@Shy, may be simple for you but the answer is incomplete without that detail. @Aaron, you've supplied half the answer - compute the radius from the center to one of the points, then you're done. –  Mark Ransom Dec 3 '08 at 16:18

Let's say that the box is defined as a set of four points (P1, P2, P3 and P4). For the sake of simplicity, we'll say you are dragging P1, and that P3 is the opposite corner (the one you are using as an anchor).

Let's label the mouse position as M, and the new points you wish to calculate as N1, N2 and N4. P3 will, of course, remain the same.

Your scaling factor can be simply computed using vector subtraction and the vector dot product:

``scale = ((M - P3) dot (P1 - P3)) / ((P1 - P3) dot (P1 - P3))``

And the three new points can be found using scalar multiplication and vector addition:

``````N1 = scale*P1 + (1 - scale)*P3
N2 = scale*P2 + (1 - scale)*P3
N4 = scale*P4 + (1 - scale)*P3``````

edit: I see that MizardX has answered the question already, so my answer is here to help with that difficult explanation. I hope it helps!

edit: here is the algorithm for non-proportional scaling. In this case, N1 is equal to M (the point being dragged follows the mouse), so the only points of interest are N2 and N4:

``````N2 = ((M - P3) dot (P2 - P3)) / ((P2 - P3) dot (P2 - P3)) * (P2 - P3) + P3
N4 = ((M - P3) dot (P4 - P3)) / ((P4 - P3) dot (P4 - P3)) * (P4 - P3) + P3``````

where * represents scalar multiplication

edit: Here is some C++ code which answers the question. I'm sure this question is long-dead by now, but it was an interesting problem, and I had some fun writing the code.

``````#include <vector>

class Point
{
public:
float x;
float y;
Point() { x = y = 0; }
Point(float nx, float ny) { x = nx; y = ny; }
};

Point& operator-(Point& A, Point& B) { return Point(A.x-B.x, A.y-B.y); }
Point& operator+(Point& A, Point& B) { return Point(A.x+B.x, A.y+B.y); }
Point& operator*(float sc, Point& P) { return Point(sc*P.x, sc*P.y); }

float dot_product(Point A, Point B) { return A.x*B.x + A.y*B.y; }

struct Rect { Point point[4]; };

void scale_points(Rect box, int anchor, Point mouse, vector<Point> points)
{
Point& P3 = box.point[anchor];
Point& P2 = box.point[(anchor + 1)%4];
Point& P1 = box.point[(anchor + 2)%4];
Point& P4 = box.point[(anchor + 3)%4];

Point A = P4 - P3;
Point aFactor = dot_product(mouse - P3, A) / dot_product(A, A) * A;

Point B = P2 - P3;
Point bFactor = dot_product(mouse - P3, B) / dot_product(B, B) * B;

for (int i = 0; i < points.size(); i++)
{
Point P = points[i] - P3;
points[i] = P3 + dot_product(P, aFactor) + dot_product(P, bFactor);
}
}``````
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Thanks, but this only seems to work for proportionate scaling. Is there any way to make it work for unproportionate? –  Menno Dec 3 '08 at 9:14
My mistake. I thought you were looking for proportionate scaling. –  e.James Dec 3 '08 at 15:12
and I probably should have made that a little more clear ;) –  Menno Dec 3 '08 at 15:32
No worries. This was a fun one! I have added the algorithm for non-proportional scaling. –  e.James Dec 3 '08 at 17:51